Low rigidity gels for MSC growth modulation

ABSTRACT

This invention provides gels and matrices having a rigidity in the range of 0.1-2.5 kPa, methods of manufacturing same, and method of preserving a mesenchymal stem cell population or studying mesenchymal stem cells, comprising same.

FIELD OF INVENTION

This invention provides methods of modulating stem cell development using soft-gels. Specifically, the invention provides methods, compositions and devices for modulating the development of stem cells, using gels having optimized viscoelastic properties.

BACKGROUND OF THE INVENTION

Adult mesenchymal stem cells have the ability to self-renew and differentiate into multiple cell lineages of mesenchymal tissues. Therefore, clinical applications of these cells, such as replacement of damaged tissues or carriers for anti-cancer agents, have been considered. Applications of adult mesenchymal stem cells are still limited to preclinical stage at this time, in part because of rapid aging of these cells ex vivo, which limits their expansion and engineering. Immortalizing mesenchymal stem cells by telomerase transduction is reported to overcome issues associated with accelerated aging. However, their ability of unlimited self-renewal may lead to an out-of-control growth, once they are implanted into tissues. In fact, transformation of telomerase-transduced mesenchymal stem cells was observed in in vitro settings.

Thus, regulation of the growth of adult mesenchymal stem cells is one of the key steps toward their clinical applications.

SUMMARY OF THE INVENTION

This invention provides methods of modulating stem cell development using soft-gels. Specifically, the invention provides methods, compositions and devices for modulating the development of stem cells, using gels having optimized viscoelastic properties.

In another embodiment, the invention provide s a method of manufacturing a fibrin matrix having a rigidity in a range of 0.1-2.5 kPa, comprising the steps of polymerizing a composition comprising a fibrin or fibrinogen protein, thereby producing a soft fibrin matrix, wherein the concentration of said fibrin or fibrinogen protein in said soft fibrin matrix is 1-20 mg/ml, and coating said soft fibrin matrix with a composition comprising an adhesion protein.

In another embodiment, the present invention provides a method of preserving a mesenchymal stem cell population, said method comprising the step of culturing said mesenchymal stem cell population in a gel matrix having a rigidity in a range of 0.1-2.5 kPa.

In another embodiment, the present invention provides an apparatus for modulating growth of a mesenchymal stem cell comprising: a gel matrix having a rigidity in a range of 150-750 Pa; and an adipocyte induction medium, wherein said gel or matrix is coated with a type 1 collagen, a fibronectin, or a combination thereof.

In another embodiment, the present invention provides a gel matrix comprising a gelling agent and an acrylamide-bisacrylamide mixture wherein said gel matrix is coated with a type 1 collagen, a fibronectin, or a combination thereof and having a rigidity in a range of 150-750 Pa.

In one embodiment, the invention provides a method of modulating development of a mesenchymal stem cell, comprising the step of suspending the mesenchymal stem cell in a gel matrix comprising a gelling agent wherein said gel matrix is coated with a type 1 collagen, a fibronectin, or a combination thereof and wherein said gel matrix is maintained at a predetermined rigidity; and exposing the gel matrix to a growth modulating factor.

In another embodiment, the invention provides a method for inducing or maintaining quiescence and sustaining biological activity in a somatic stem cell ex vivo, comprising: contacting the somatic stem cell with a gel matrix comprising an extracellular material that bind to integrin on the membrane of the somatic stem cell, said gel matrix having a substantially similar elasticity to the elasticity of the predominant in vivo biological microenvironment of the somatic stem cell of the same type in vivo; and providing the somatic stem cell with nutrient material for sustaining biological activity of the somatic stem cell ex vivo.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1. A. Mechanical properties of polyacrylamide substrates. The shear modulus of polyacrylamide gels with a range of acrylamide (indicated as percents near data lines) to bisacrylamide (indicated as crosslinker) proportions was measured. The shear modulus (G′), expressed in Pascal, increases at constant polymer mass with increasing crosslinker. Increasing the concentration of acrylamide from 3 to 12% also creates a large stiffness range from 10 to 50,000 Pa. The solid line denotes the theoretical stiffness of a rubberlike network if every crosslink was elastically effective. B. Cell shape and F-actin structure of hMSC on stiff or soft matrices. C. Cell shape and F-actin structure of hMSC on soft gels and glass.

FIG. 2. BrdU incorporation into hMSC.

FIG. 3. The effect of matrix rigidity on adipocyte differentiation. A. Graph of percent positive cells. First bar in each series: Oil Red O-staining. Second bar: PPARγ2 staining.

FIG. 4. F-actin structure in astrocytes seeded either on stiff or soft gels.

FIG. 5. Quantification of increase in Rho activity from soft to hard gels. Astrocytes were seeded on polyacrylamide gels with various stiffness. GTP-loading level of Rho was quantified.

FIG. 6. Melanoma cells spread more on stiff matrices. Graphical representation of area.

FIG. 7. Melanoma cells adhered to soft and stiff gels with same efficiency.

FIG. 8. Larger population of melanoma cells on stiff gels.

FIG. 9. show images of human MSCs on several substrates of different elasticities according to various embodiments of the present invention.

FIG. 10 shows the amount of bromodeoxyuridine (BrdU) uptake into human MSCs on substrates of varying elasticities according to various embodiments of the invention.

FIG. 11 shows (A-D) an illustration of the effect of a quasi 3D environment on stem cell shape and proliferation according to various embodiments of the invention.

FIG. 12 shows the response of human MSCs to adipogenic induction media according to various embodiments of the invention.

FIG. 13 shows calcium deposition visualized with Alizarin Red S after stimulation of human MSCs with osteoinduction media according to various embodiments of the invention.

FIG. 14 shows a flow chart for preparing a system for inducing quiescence, differentiation, and proliferation in adult stem cells according to various embodiments of the invention.

FIG. 15 shows schematic illustrations of embodiments of systems of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

This invention provides gels and matrices having a rigidity in the range of 0.01-50 kPa, methods of manufacturing same, and method of preserving a mesenchymal stem cell population or studying mesenchymal stem cells, comprising same.

In another embodiment, provided herein is a method of manufacturing a fibrin matrix with a rigidity in a range of 150-750 Pa, comprising the steps of polymerizing a composition comprising a fibrin or fibrinogen protein, thereby producing a soft fibrin matrix, wherein the concentration of the fibrin or fibrinogen protein in the soft fibrin matrix is 3-10 mg/mL, and coating the soft fibrin matrix with a composition comprising an adhesion protein, thereby manufacturing a fibrin matrix having a rigidity in a range of 150-750 Pa.

In another embodiment, provided herein is a method of inducing quiescence of a transformed cell, comprising the step of culturing the transformed cell in a gel or matrix of the present invention, thereby inducing quiescence of a transformed cell. In another embodiment, the transformed cell is a cancer cell. In another embodiment, the transformed cell is a neoplastic cell. In another embodiment, the transformed cell is any other type of transformed cell known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment of methods and compositions of the present invention, the telomerase length of the mesenchymal stem cell population is maintained. “Maintained” refers, in another embodiment, to a lack of substantial change in the length. In another embodiment, the term refers to a lack of measurable change in the length. In another embodiment, the term refers to a lack of sufficient change in the length to affect proliferative capacity. Each possibility represents a separate embodiment of the present invention.

In another embodiment of methods and compositions of the present invention, the mesenchymal stem cell population is maintained in a quiescent state. “Quiescent” refers, in another embodiment, to a lack of significant replication. In another embodiment, the term refers to a significantly reduced level of replication. In another embodiment, the term refers to a large percentage of cells arrested in the cell cycle. In another embodiment, the cells are arrested at the G1 phase. In another embodiment, the cells are arrested in the G2 phase. In another embodiment, “quiescent” refers to any other art-accepted definition of the term. Each possibility represents a separate embodiment of the present invention.

In one embodiment, embodiment, when the stem cell is a bone marrow-derived human mesenchymal cell, the extracellular matrix (ECM) has an elasticity of about 250 Pa, and comprises a mixture of collagen and fibronectin. In another embodiment, the collagen is rat tail collagen, and the fibronectin is human fibronectin. The ratio of the collagen and fibronectin may vary, and in an embodiment, the ratio of collagen to fibronectin is approximately 5:1. Other ratios of collagen and fibronectin may be used. One of ordinary skill in the art will appreciate that collagen and fibronectin can be obtained from other sources, and that substances other than collagen and fibronectin may be used to present elasticity and bind to integrins on the surface of the cell membrane so that quiescence of the cell is induced.

According to embodiments of the present invention, the extracellular material (ECM) is provided with an appropriate apparent elasticity by coupling the ECM with a substrate such that a stem cell contacting the ECM senses the elasticity of the substrate. Correspondingly, the substrate may be a material whose elasticity, when coupled to the ECM, is sensed by a stem cell contacting the ECM. In some embodiments, the substrate is glass. In other embodiments, the substrate is a gel with elasticity of 250 Pa, or a gel with elasticity of 7500 Pa. These gels may be polyacrylamide gels, and, as known to those with skill in the art, the elasticity of polyacrylamide gels may be varied, for example, by changing the concentrations of acrylamide and bisacrylamide in the gel formulation. The manufacture of gels of varying elasticity that may be used in the method of the present invention will be apparent to one of skill in the art in light of this specification.

The elasticity of the in vivo biological environment of a stem cell may be determined by extracting a sample of physiological tissue from the immediate in vivo environment of the stem cell, and then measuring the shear modulus of that tissue sample. Exemplary procedures for preparing and measuring the elasticity of rat tissue and bovine tissue are described in this specification. Table 1 below provides the elasticity of various types of tissues:

TABLE 1 Elasticity (in Pa) Species Tissue (mean ± SD) Bovine Bone marrow 220 ± 50 Rat Subcutaneous fat 160 ± 70 Rat Visceral fat 130 ± 70 Rat Liver 403 ± 28 Rat Skeletal muscle 2251 ± 166

In one embodiment, human MSCs on 250 Pa gels are in a quiescent state awaiting a further signal to determine their fate. In one embodiment, the hMSC's will undergo adipogenic differentiation (induced by chemical factors), or in other embodiments, a return to the cell cycle (induced by coupling the cells to a stiff surface), or osteogenic differentiation (which appears to require both chemical induction and a stiff substrate). Stimulating cells cultured on soft gels with adipogenic differentiation factors results in one embodiment, in a remarkably high number of cells accumulating lipid droplets. In one embodiment, chemical induction is required for osteoblast differentiation. The requirement for synchronized mechanical and chemical stimulation explains in one embodiment, how human MSCs can be compartmentalized into compliant tissues such as bone marrow and yet resist spontaneous differentiation.

Like matrix elasticity, in another embodiment the choice of extracellular ligand strongly affects human MSC adhesion and differentiation. Collagen type 1 is found in a variety of tissues including bone and adipose, and it is regularly used as a substrate for cell adhesion experiments. In one embodiment, on 250 Pa gel, collagen alone does not ensure efficient adhesion of a majority of cells. In one embodiment, a mixture of collagen type I and fibronectin at a ratio of 10:1 provides the best adhesion of cells to the 250 Pa gels without affecting differentiation potential.

Human MSCs have the capacity to remodel their microenvironment by altering the expression of matrix metalloproteases, and this helps in one embodiment to promote efficient differentiation after an initial strong adhesion is achieved.

In one embodiment, DNA synthesis in human MSCs decreases dramatically when human MSCs are cultured on soft gels, developing a round phenotype. This is in contrast with other proliferating cell types such as NIH 3T3 fibroblasts, bovine aortic endothelial cells, and NRK epithelial cells which all continue to divide when cultured on soft gels. Thus, stem cell quiescence on 250 Pa gels is not a general shape-induced failure of cytokinesis, but rather a specific sensitivity of these cells to substrate compliance. Accordingly and in one embodiment, provided herein is a method of maintaining stem cells in a quiescent state, comprising suspending the stem cells in a fibronectin/collagen gel having G′ of 250 Pa.

In one embodiment, when nonproliferating human MSCs are presented with a protein gel matrix-coated glass substrate, the cells develop a spindle morphology and reenter the cell cycle. In another embodiment, the presence of a stiff substrate overrides the physical cues from a compliant matrix. In one embodiment, no significant population of cells exhibiting a neuronal phenotype with neurite-like protrusions, are present on soft 250 Pa gels without any chemical induction.

In one embodiment, substrate elasticity regulates differentiation of cells with specific phenotypes. In another embodiment, mechanical properties alone do not direct stem cell differentiation. This is because several tissues in the body have similar elasticities. For example, brain, fat, and bone marrow tissues all have a storage modulus of approximately 200 Pa, yet all maintain unique populations of cells. In another embodiment, in vivo human MSCs are stored in an individual's bone marrow for decades and yet retain multipotency. In one embodiment, human MSCs are cultured ex vivo on stiff tissue culture plastic and retain multipotency for several passages. In one embodiment, both mechanical and chemical stimuli are integrated by the cell to determine its response. In another embodiment, while chemical stimuli can override the influences of substrate mechanics, in other embodiments, an inappropriate mechanical environment prevents a normal cellular response to chemical agonists. In one embodiment, quiescent cells differentiate into osteoblasts only as a result of changing both their physical and chemical environments to those that stimulate osteogenesis. Accordingly and in one embodiment, a matrix with appropriate elasticity has the capability to maintain a quiescent population of multipotent bone marrow mesenchymal stem cells that respond to both mechanical and chemical stimuli that drive proliferation and differentiation.

FIG. 14 illustrates a flow chart for preparing an embodiment of a system for inducing quiescence, differentiation, and proliferation in adult stem cells according to various embodiments of the present invention. Solutions of acrylamide and bisacrylamide are prepared in phosphate buffered saline (PBS) to a total volume of 500 μl. In one embodiment, adjusting the concentration of acrylamide and bisacrylamide enables obtaining a wide range of rigidity. Polymerization is initiated with TEMED (N,N,N′,N′-Tetramethylethylenediamine) and ammonium persulfate to form a gel. In step 601, Acrylamide/bisacrylamide (polyacrylamide) solution, a droplet (for example, about 200 μl) of the polymerized gel is deposited on a glass coverslip previously modified with 3-aminopropyltrimethoxysilane and glutaraldehyde. In step 602, overlay with N-hydroxysuccinimide in toluene, approximately 15 μl of 2% acrylic acid N-hydroxysuccinimide ester in toluene is applied to the solution of step 601, and, in stem 603, Top Coverslip, a chlorosilanized coverslip is placed on top of the droplet. In step 604, Remove coverslip, the top coverslip is removed after polymerization is completed and, optionally, the gel is illuminated with ultraviolet light for approximately 10-15 minutes (not shown). In step 605, ECM ligand, N-succinimide acrylate on the top of the gel is reacted with an extracellular matrix ligand, which in an embodiment is a mixture of 0.1 mg/ml of collagen type 1 and 0.02 mg/ml fibronectin. In a further step (not depicted), gels are washed 3 times with PBS and left in PBS until step 606, Cells on gel, when stem cells are seeded on the cells. When bone marrow-derived mesenchymal stem cells are seeded on this material, cells become quiescent even in the presence of chemical stimuli to cause proliferation or differentiation.

Accordingly and in one embodiment, provided herein is a method for inducing or maintaining quiescence and sustaining biological activity in a somatic stem cell ex vivo, comprising: contacting the somatic stem cell with a gel matrix comprising an extracellular material that bind to integrin on the membrane of the somatic stem cell; said gel matrix having a substantially similar elasticity to the elasticity of the predominant in vivo biological microenvironment of the somatic stem cell of the same type in vivo; and providing the somatic stem cell with nutrient material for sustaining biological activity of the somatic stem cell ex vivo.

In a method of the present invention, a stem cell may be contacted with appropriate ECM in various ways. For example, as described in this specification, the ECM may form a layer coupled to the substrate, and the stem cell may be placed on the ECM. Alternatively, the cell may be placed on ECM coupled to the substrate and additionally contacted by ECM placed on the cell, for example by placing on the cell a structure coupling ECM to a substrate that presents the appropriate apparent elasticity to the stem cell.

In another embodiment, there may be two formulations of ECM: a first formulation, which may or may not include nutrient materials, that is coupled to the substrate; and a second formulation that includes nutrient materials and that is not coupled with the substrate. Structures and configurations for contacting stem cells with an appropriate ECM (including substrates and, optionally, linking materials for linking the substrate to the ECM), are described in this specification, including for example FIG. 6, and are apparent to one of skill in the art in light of this specification.

In embodiments of methods of the present invention, a stem cell that is not in a quiescent state is contacted with ECM according to methods of the present invention so that quiescence is induced into the cell and it transitions from a non-quiescent state to a quiescent state. In other embodiments, a quiescent stem cell is contacted with ECM according to methods of the present invention so that quiescence is maintained in the cell and it does not transition from a quiescent state.

Accordingly and in one embodiment, provided herein is a method of modulating development of a mesenchymal stem cell, comprising the step of suspending the mesenchymal stem cell in a gel matrix comprising a gelling agent wherein said gel matrix is coated with a type I collagen, a fibronectin, or a combination thereof and wherein said gel matrix is maintained at a predetermined rigidity; and exposing the gel matrix to a growth modulating factor, whereby exposure to the chemical or physical factor results in an increase in the rigidity of the gel matrix to coincide with the rigidity of the ECM in the microenvironment the mesenchymal stem cell is sought to differentiate into.

In another embodiment, over 80% of the cells are cell cycle arrested. In another embodiment, at least 80% of the cells are cell cycle arrested. In another embodiment, over 70% of the cells are cell cycle arrested. In another embodiment, at least 70% of the cells are cell cycle arrested. In another embodiment, over 75% of the cells are cell cycle arrested. In another embodiment, at least 75% of the cells are cell cycle arrested. In another embodiment, over 82% of the cells are cell cycle arrested. In another embodiment, at least 82% of the cells are cell cycle arrested. In another embodiment, over 85% of the cells are cell cycle arrested. In another embodiment, at least 85% of the cells are cell cycle arrested. In another embodiment, over 87% of the cells are cell cycle arrested. In another embodiment, at least 87% of the cells are cell cycle arrested. In another embodiment, over 90% of the cells are cell cycle arrested. In another embodiment, at least 90% of the cells are cell cycle arrested. In another embodiment, over 92% of the cells are cell cycle arrested. In another embodiment, at least 92% of the cells are cell cycle arrested. In another embodiment, over 93% of the cells are cell cycle arrested. In another embodiment, at least 93% of the cells are cell cycle arrested. In another embodiment, over 94% of the cells are cell cycle arrested. In another embodiment, at least 94% of the cells are cell cycle arrested. In another embodiment, over 95% of the cells are cell cycle arrested. In another embodiment, at least 95% of the cells are cell cycle arrested. In another embodiment, over 96% of the cells are cell cycle arrested. In another embodiment, at least 96% of the cells are cell cycle arrested. In another embodiment, over 97% of the cells are cell cycle arrested. In another embodiment, at least 97% of the cells are cell cycle arrested. In another embodiment, over 98% of the cells are cell cycle arrested. In another embodiment, at least 98% of the cells are cell cycle arrested. In another embodiment, over 99% of the cells are cell cycle arrested. In another embodiment, at least 99% of the cells are cell cycle arrested. Each possibility represents a separate embodiment of the present invention.

In another embodiment, replication is reduced by 50%, relative to replication in a tissue culture dish. In another embodiment, replication is reduced by 60% relative to a tissue culture dish. In another embodiment, replication is reduced by 65% relative to a tissue culture dish. In another embodiment, replication is reduced by 70% relative to a tissue culture dish. In another embodiment, replication is reduced by 75% relative to a tissue culture dish. In another embodiment, replication is reduced by 80% relative to a tissue culture dish. In another embodiment, replication is reduced by 85% relative to a tissue culture dish. In another embodiment, replication is reduced by 90% relative to a tissue culture dish. In another embodiment, replication is reduced by 95% relative to a tissue culture dish. In another embodiment, replication is reduced by 97% relative to a tissue culture dish. In another embodiment, replication is reduced by over 97% relative to a tissue culture dish. In another embodiment, replication is reduced by over 98% relative to a tissue culture dish. In another embodiment, replication is reduced by over 99% relative to a tissue culture dish. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a method of the present invention further comprises the step of subsequently (e.g. following culturing in the presence of a gel or matrix of the present invention) plating the mesenchymal stem cell population in a tissue-culture apparatus. In another embodiment, the tissue culture apparatus contains induction medium. In another embodiment, the step of subsequently plating is performed with chemical induction. Each possibility represents a separate embodiment of the present invention.

In another embodiment, provided herein is a method of studying proliferation or differentiation of a mesenchymal stem cell, comprising the step of culturing the mesenchymal stem cell in a gel or matrix with a rigidity in a range of 150-750 Pa, thereby studying proliferation or differentiation of a mesenchymal stem cell.

The adipocyte population of methods and compositions of the present invention is, in another embodiment, a population comprising adipocytes. In another embodiment, the population is enriched for adipocytes. In another embodiment, the population is a partially purified adipocytes population. In another embodiment, the adipocytes are isolated from a biological source, followed by a purification or enrichment step. In another embodiment, isolation from the biological source is followed by culturing. In another embodiment, isolation from the biological source is followed by culturing and a purification or enrichment step. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the cell population of methods and compositions of the present invention is cultured in the presence of a gel or matrix of methods and compositions of the present invention. In another embodiment, the cell population is cultured in the gel or matrix. In another embodiment, the cell population is cultured on the gel or matrix. In another embodiment, the cell population is cultured in a tissue culture apparatus containing the gel or matrix. Each possibility represents a separate embodiment of the present invention.

“Mesenchymal stem cell population” refers, in another embodiment, to a population comprising mesenchymal stem cells (MSC). In another embodiment, the population is enriched for MSC. In another embodiment, the population is a partially purified MSC population. In another embodiment, the MSC are isolated from a biological source, followed by a purification or enrichment step. In another embodiment, isolation from the biological source is followed by culturing. In another embodiment, isolation from the biological source is followed by culturing and a purification or enrichment step. Each possibility represents a separate embodiment of the present invention.

“Mesenchymal” cells of methods and compositions of the present invention are isolated or purified, in another embodiment, from bone marrow. In another embodiment, the cells are bone marrow-derived mesenchymal stem cell. In another embodiment, the cells are isolated or purified from adipose tissue. In another embodiment, the cells are isolated or purified from cartilage. In another embodiment, the cells are isolated or purified from any other tissue known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a gel or matrix of methods and compositions of the present invention has a stiffness of 150-750 pascals (Pa). In another embodiment, a gel or matrix of methods and compositions of the present invention has a shear modulus of 150-750 Pa. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a gel or matrix of methods and compositions of the present invention has a stiffness equivalent to a biological tissue. In another embodiment, the biological tissue is bone marrow. In another embodiment, the biological tissue is fat tissue. In another embodiment, the biological tissue is any other biological tissue known in the art. Each possibility represents a separate embodiment of the present invention.

In one embodiment, the gel matrix described herein are capable of forming gels of various strength, depending on their structure and concentration as well as, in another embodiment, environmental factors such as ionic strength, pH and temperature. The combined viscosity and gel behavior referred to as “viscoelasticity” in one embodiment, are examined by determining the effect that an oscillating force has on the movement of the material. In another embodiment elastic modulus (G′), viscous modulus (G″), and complex viscosity (η*) are the parameters sought to be changed using the methods described herein, and these are analyzed in another embodiment by varying either stress or strain harmonically with time (Table 1). These parameters are derived from the complex modulus (G*), which is the ratio of maximum stress to maximum strain, and the phase angle (ω), which is the angle that the stress and strain are out of phase.

TABLE 2 Relationships between dynamic moduli, phase angle (δ), and frequency (ω). Term Symbol Definition Information provided Complex modulus G* [(G′)² + All viscoelastic characteristics (G″)²]^(0.5) Elastic modulus, G′ G* cos δ Energy stored per deformation storage modulus cycle; solid-like or elastic behavior Viscous modulus, G″ G* sin δ Energy dissipated per loss modulus deformation cycle; gluid-like or viscous behavior Complex viscosity η* G*/ω Viscoelastic flow

In one embodiment, in the gel matrices described herein, some of the deformation caused by shear stress is elastic and will return to zero when the force is removed. The remaining deformation such as that deformation created by the sliding displacement of the chains through the solvent in one embodiment will not return to zero when the force is removed. Under a constant force the elastic displacement remains constant in one embodiment, whereas the sliding displacement continues, so increasing.

In one embodiment, the term “elastic,” or “elasticity,” and like terms refer to a physical property of the gel matrices described herein, namely the deformability of the gel under mechanical force and the ability of the gel matrix to retain its original shape when the deforming force is removed. In another embodiment, the term “elastic modulus” refers to Young's Modulus and is a measure of the ratio of (a) the uniaxial stress along an axis of the material to (b) the accompanying normal strain along that axis.

The shear modulus (resulting from changing strain) is the ratio of the shear stress to the shear strain. It follows from the complex relationship similar to the above that: G*=G′+iG″

where G* is the complex shear modulus, G′ is the in-phase storage modulus, i is a material-related factor and G″ is the out-of-phase similarly-directed loss modulus; G*=E(G′2+G″2). The frequency where these parameters cross over corresponds to a relaxation time (τ) specific for the material.

In one embodiment, linear viscoelastic properties of the gel matrices described herein are determined by measurements in an oscillating shear flow at small amplitude and with variable angular frequency. The values for G′ and G″ are determined to a great extent here by the concentration of the cellulose derivatives in the aqueous solution and the magnitude of the representative viscosity value. Therefore, hereinafter, only the relative course of G′ and G″ with increasing angular frequency

, is considered. In another embodiment, at a concentration of 1.5 to 2% (w/w) of cellulose derivative of aqueous solution and a temperature of approximately 20° C., the behavior of G′ and G″ for the cellulose derivatives is such that at a low angular frequency (

, the storage modulus G′ is less than the loss modulus G″, but with increasing angular frequency G′ increases more greatly than G″. In another embodiment, G′, above a certain angular frequency, finally becomes greater than G″, and the solution at high values of angular frequency thus predominantly reacts elastically. This behavior is attenuated or changed using the modulating methods described herein.

In another embodiment, the term “Elasticity” refers to the physical property of a material that defines its ability to deform by stress, whether or not the deformation is reversible. As used in this specification, elasticity and rigidity are inversely related, and the elasticity (rigidity) of a material may be measured by using an RFS III fluids spectrometer rheometer, available from Rheometrics, Piscataway, N.J., using a 2% oscillatory shear strain at a frequency of 10 radians per second. Elasticity and other 10 rheological properties of cells and other physiological tissues can be measured using any of a variety of methods known to those skilled in the art. Such methods may involve the use of rheometers or atomic force microscopes, as examples. (See, e.g., Engler A J, Rehfeldt F, Sen S, Discher D E, “Microtissue elasticity: measurements by atomic force microscopy and its influence on cell differentiation,” Methods Cell Biol. 2007; 83:521-45; 15 Yeung T, Georges P C, Flanagan L A, Marg B, Ortiz M, Funaki M, Zahir N, Ming W, Weaver V, Janmey P A, “Effects of substrate stiffness on cell morphology, cytoskeletal structure, and adhesion,” Cell Motil Cytoskeleton. 2005 January; 60(1):24-34.).

In one embodiment, the term “Intrinsic viscosity ([η*]) refers to the limit of the reduced viscosity extrapolated to zero concentration. As with the reduced viscosity, it has units of reciprocal concentration, for example, mL·g⁻¹.

In one embodiment, rigidity or stiffness, refers to the G′ values observed or measured.

In another embodiment, a gel or matrix of methods and compositions of the present invention is coated with a solution comprising an adhesion protein. In another embodiment, the adhesion protein is a collagen. In another embodiment, the adhesion protein is a type 1 collagen. In another embodiment, the adhesion protein is a fibronectin. In another embodiment, the adhesion protein is any other adhesion protein known in the art. In another embodiment, the gel or matrix is coating with a solution comprising a combination of adhesion proteins. In another embodiment, the gel or matrix is coating with a solution comprising a collagen and a fibronectin. In another embodiment, the gel or matrix is coating with a solution comprising a type I collagen and a fibronectin. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the collagen of methods and compositions of the present invention is a recombinant collagen. In another embodiment, the collagen is purified from a biological source. In another embodiment, the collagen is a type I collagen. In another embodiment, the collagen is any other type of collagen known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the fibronectin of methods and compositions of the present invention is a recombinant fibronectin. In another embodiment, the fibronectin is purified from a biological source. In another embodiment, the fibronectin is a type I fibronectin. In another embodiment, the fibronectin is any other type of fibronectin known in the art. Each possibility represents a separate embodiment of the present invention.

The gelling agent of methods and compositions of the present invention is, in another embodiment, an acrylamide. In another embodiment, the gelling agent is an acrylamide-bisacrylamide mixture. In another embodiment, the gelling agent comprises acrylamide. In another embodiment, the gelling agent comprises an acrylamide-bisacrylamide mixture. Each possibility represents a separate embodiment of the present invention.

In another embodiment, an acrylamide gel of methods and compositions of the present invention has an acrylamide: bisacrylamide ratio of between 100:1 and 30:1. In another embodiment, the acrylamide gel is prepared from a solution having an acrylamide:bisacrylamide ratio of between 100:1 and 30:1. In another embodiment, the ratio is between 100:1 and 20:1. In another embodiment, the acrylamide:bisacrylamide ratio is between 100:1 and 40:1. In another embodiment, the ratio is between 100:1 and 50:1. In another embodiment, the ratio is between 100:1 and 60:1. In another embodiment, the ratio is between 100:1 and 70:1. In another embodiment, the ratio is between 120:1 and 30:1. In another embodiment, the ratio is between 120:1 and 40:1. In another embodiment, the ratio is between 120:1 and 50:1. In another embodiment, the ratio is between 120:1 and 60:1. In another embodiment, the ratio is between 120:1 and 70:1. In another embodiment, the ratio is between 90:1 and 20:1. In another embodiment, the ratio is between 90:1 and 30:1. In another embodiment, the ratio is between 90:1 and 40:1. In another embodiment, the ratio is between 90:1 and 50:1. In another embodiment, the ratio is between 90:1 and 60:1. In another embodiment, the ratio is between 80:1 and 20:1. In another embodiment, the ratio is between 80:1 and 30:1. In another embodiment, the ratio is between 80:1 and 40:1. In another embodiment, the ratio is between 80:1 and 50:1.

In another embodiment, the ratio is 30:1. In another embodiment, the ratio is 20:1. In another embodiment, the ratio is 25:1. In another embodiment, the ratio is 35:1. In another embodiment, the ratio is 40:1. In another embodiment, the ratio is 45:1. In another embodiment, the ratio is 50:1. In another embodiment, the ratio is 55:1. In another embodiment, the ratio is 60:1. In another embodiment, the ratio is 65:1. In another embodiment, the ratio is 70:1. In another embodiment, the ratio is 75:1. In another embodiment, the ratio is 80:1. In another embodiment, the ratio is 85:1. In another embodiment, the ratio is 90:1. In another embodiment, the ratio is 95:1. In another embodiment, the ratio is 100:1.

Each acrylamide:bisacrylamide ratio represents a separate embodiment of the present invention.

In another embodiment, an acrylamide gel of methods and compositions of the present invention has a total acrylamide concentration of 3-5%. In another embodiment, the acrylamide gel is prepared from a solution having a total acrylamide concentration of 3-5%. In another embodiment, the total acrylamide concentration is 2%. In another embodiment, the concentration is 2.5%. In another embodiment, the concentration is 3%. In another embodiment, the concentration is 3.5%. In another embodiment, the concentration is 4%. In another embodiment, the concentration is 4.5%. In another embodiment, the concentration is 5%. In another embodiment, the concentration is 5.5%. In another embodiment, the concentration is 6%. In another embodiment, the concentration is 2-5%. In another embodiment, the concentration is 2.5-5%. In another embodiment, the concentration is 3.5-5%. In another embodiment, the concentration is 2-4%. In another embodiment, the concentration is 2-4.5%. In another embodiment, the concentration is 2-5%. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the gelling agent of methods and compositions of the present invention is a fibrin protein. In another embodiment, the gelling agent is a fibrinogen protein. In another embodiment, the fibrinogen is depleted of clotting factors. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the concentration of the recombinant fibrin or fibrinogen protein in a gel or matrix of methods and compositions of the present invention is 3-10 mg/mL. In another embodiment, the concentration is 3-12 mg/mL. In another embodiment, the concentration is 3-9 mg/mL. In another embodiment, the concentration is 3-8 mg/mL. In another embodiment, the concentration is 3-7 mg/mL. In another embodiment, the concentration is 3-6 mg/mL. In another embodiment, the concentration is 2-12 mg/mL. In another embodiment, the concentration is 2-10 mg/mL. In another embodiment, the concentration is 2-9 mg/mL. In another embodiment, the concentration is 2-8 mg/mL. In another embodiment, the concentration is 2-7 mg/mL. In another embodiment, the concentration is 2-6 mg/mL. In another embodiment, the concentration is 4-12 mg/mL. In another embodiment, the concentration is 4-10 mg/mL. In another embodiment, the concentration is 4-9 mg/mL. In another embodiment, the concentration is 4-8 mg/mL. In another embodiment, the concentration is 4-7 mg/mL. In another embodiment, the concentration is 5-12 mg/mL. In another embodiment, the concentration is 5-10 mg/mL. In another embodiment, the concentration is 5-9 mg/mL. In another embodiment, the concentration is 5-8 mg/mL. In another embodiment, the concentration is 2 mg/mL. In another embodiment, the concentration is 2.5 mg/mL. In another embodiment, the concentration is 3 mg/mL. In another embodiment, the concentration is 3.5 mg/mL. In another embodiment, the concentration is 4 mg/mL. In another embodiment, the concentration is 4.5 mg/mL. In another embodiment, the concentration is 5 mg/mL. In another embodiment, the concentration is 6 mg/mL. In another embodiment, the concentration is 7 mg/mL. In another embodiment, the concentration is 8 mg/mL. In another embodiment, the concentration is 9 mg/mL. In another embodiment, the concentration is 10 mg/mL. In another embodiment, the concentration is 11 mg/mL. In another embodiment, the concentration is 12 mg/mL. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a fibrin or fibrinogen protein of methods and compositions of the present invention is a fibrin or fibrinogen protein of a heterothermic animal. In another embodiment, the fibrin or fibrinogen protein is a fibrin or fibrinogen protein of a homeothermic animal. In another embodiment, the fibrin or fibrinogen is from a fish. In another embodiment, the fibrin or fibrinogen is from a salmon. In another embodiment, the fibrin or fibrinogen is from any other fish known in the art. In another embodiment, the fibrin or fibrinogen is from any other heterothermic known in the art. In another embodiment, the fibrin or fibrinogen is from a mammal. In another embodiment, the fibrin or fibrinogen is human fibrin or fibrinogen. In another embodiment, the fibrin or fibrinogen is bovine fibrin or fibrinogen. In another embodiment, the fibrin or fibrinogen is from any other mammal known in the art. In another embodiment, the fibrin or fibrinogen is from any other homoeothermic known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the gelling agent is agarose. In another embodiment, the gelling agent is agar. In another embodiment, the gelling agent is a glycosaminoglycan. In another embodiment, the gelling agent is a collagen. In another embodiment, the gelling agent is carrageen. In another embodiment, the gelling agent is carrageenan. In another embodiment, the gelling agent is locust bean gum. In another embodiment, the gelling agent is glycerine. In another embodiment, the gelling agent of methods and compositions of the present invention is any other gelling agent known in the art. Each possibility represents a separate embodiment of the present invention.

The gel or matrix of methods and compositions of the present invention is, in another embodiment, a 2-dimensional gel or matrix. In another embodiment, the gel or matrix is a 3-dimensional gel or matrix. In another embodiment, the gel or matrix is any other type of gel or matrix known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a gel or matrix of methods and compositions of the present invention further comprises an animal serum. In another embodiment, the animal serum is a fetal bovine serum. In another embodiment, the animal serum is a bovine calf serum. In another embodiment, the animal serum is a horse serum. In another embodiment, the animal serum is any other type of growth factor-containing animal serum known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a gel or matrix of methods and compositions of the present invention further comprises a protease inhibitor.

In another embodiment, a protease inhibitor of methods and compositions of the present invention inhibits the function of a peptidase. In another embodiment, the protease inhibitor is a protein. In some embodiments, the protease inhibitor is a cysteine protease inhibitor, a serine protease inhibitor (serpin), a trypsin inhibitor, a threonine protease inhibitor, an aspartic protease inhibitor, or a metallo-protease inhibitor. In another embodiment, a protease inhibitor is a suicide inhibitor, a transition state inhibitor, or a chelating agent.

In another embodiment, the protease inhibitor is soybean trypsin inhibitor (SBTI). In another embodiment, the protease inhibitor is AEBSF-HCl. In another embodiment, the inhibitor is (epsilon)-aminocaproic acid. In another embodiment, the inhibitor is (alpha) 1-antichymotypsin. In another embodiment, the inhibitor is antithrombin III. In another embodiment, the inhibitor is (alpha) 1-antitrypsin ([alpha]1-proteinase inhibitor). In another embodiment, the inhibitor is APMSF-HCl (4-amidinophenyl-methane sulfonyl-fluoride). In another embodiment, the inhibitor is sprotinin. In another embodiment, the inhibitor is benzamidine-HCl. In another embodiment, the inhibitor is chymostatin. In another embodiment, the inhibitor is DFP (diisopropylfluoro-phosphate). In another embodiment, the inhibitor is leupeptin. In another embodiment, the inhibitor is PEFABLOC® SC (4-(2-Aminoethyl)-benzenesulfonyl fluoride hydrochloride). In another embodiment, the inhibitor is PMSF (phenylmethyl sulfonyl fluoride). In another embodiment, the inhibitor is TLCK (1-Chloro-3-tosylamido-7-amino-2-heptanone HCl). In another embodiment, the inhibitor is TPCK (1-Chloro-3-tosylamido-4-phenyl-2-butanone). In another embodiment, the inhibitor is trypsin inhibitor from egg white (Ovomucoid). In another embodiment, the inhibitor is trypsin inhibitor from soybean. In another embodiment, the inhibitor is aprotinin. In another embodiment, the inhibitor is pentamidine isethionate. In another embodiment, the inhibitor is pepstatin. In another embodiment, the inhibitor is guanidium. In another embodiment, the inhibitor is alpha2-macroglobulin. In another embodiment, the inhibitor is a chelating agent of zinc. In another embodiment, the inhibitor is iodoacetate. In another embodiment, the inhibitor is zinc. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the amount of protease inhibitor utilized in methods and compositions of the present invention is 0.1 mg/liter. In another embodiment, the amount of protease inhibitor is 0.2 mg/liter. In another embodiment, the amount is 0.3 mg/liter. In another embodiment, the amount is 0.4 mg/liter. In another embodiment, the amount is 0.6 mg/liter. In another embodiment, the amount is 0.8 mg/liter. In another embodiment, the amount is 1 mg/liter. In another embodiment, the amount is 1.5 mg/liter. In another embodiment, the amount is 2 mg/liter. In another embodiment, the amount is 2.5 mg/liter. In another embodiment, the amount is 3 mg/liter. In another embodiment, the amount is 5 mg/liter. In another embodiment, the amount is 7 mg/liter. In another embodiment, the amount is 10 mg/liter. In another embodiment, the amount is 12 mg/liter. In another embodiment, the amount is 15 mg/liter. In another embodiment, the amount is 20 mg/liter. In another embodiment, the amount is 30 mg/liter. In another embodiment, the amount is 50 mg/liter. In another embodiment, the amount is 70 mg/liter. In another embodiment, the amount is 100 mg/liter.

In another embodiment, the amount of protease inhibitor is 0.1-1 mg/liter. In another embodiment, the amount of protease inhibitor is 0.2-1 mg/liter. In another embodiment, the amount is 0.3-1 mg/liter. In another embodiment, the amount is 0.5-1 mg/liter. In another embodiment, the amount is 0.1-2 mg/liter. In another embodiment, the amount is 0.2-2 mg/liter. In another embodiment, the amount is 0.3-2 mg/liter. In another embodiment, the amount is 0.5-2 mg/liter. In another embodiment, the amount is 1-2 mg/liter. In another embodiment, the amount is 1-10 mg/liter. In another embodiment, the amount is 2-10 mg/liter. In another embodiment, the amount is 3-10 mg/liter. In another embodiment, the amount is 5-10 mg/liter. In another embodiment, the amount is 1-20 mg/liter. In another embodiment, the amount is 2-20 mg/liter. In another embodiment, the amount is 3-20 mg/liter. In another embodiment, the amount is 5-20 mg/liter. In another embodiment, the amount is 10-20 mg/liter. In another embodiment, the amount is 10-100 mg/liter. In another embodiment, the amount is 20-100 mg/liter. In another embodiment, the amount is 30-100 mg/liter. In another embodiment, the amount is 50-100 mg/liter. In another embodiment, the amount is 10-200 mg/liter. In another embodiment, the amount is 20-200 mg/liter. In another embodiment, the amount is 30-200 mg/liter. In another embodiment, the amount is 50-200 mg/liter. In another embodiment, the amount is 100-200 mg/liter.

In another embodiment, the amount of protease inhibitor utilized in methods and compositions of the present invention is 1000 k.i.u. (kallikrein inactivator units)/liter. In another embodiment, the amount is 10 k.i.u./liter. In another embodiment, the amount is 12 k.i.u./liter. In another embodiment, the amount is 15 k.i.u./liter. In another embodiment, the amount is 20 k.i.u./liter. In another embodiment, the amount is 30 k.i.u./liter. In another embodiment, the amount is 40 k.i.u./liter. In another embodiment, the amount is 50 k.i.u./liter. In another embodiment, the amount is 70 k.i.u./liter. In another embodiment, the amount is 100 k.i.u./liter. In another embodiment, the amount is 150 k.i.u./liter. In another embodiment, the amount is 200 k.i.u./liter. In another embodiment, the amount is 300 k.i.u./liter. In another embodiment, the amount is 500 k.i.u./liter. In another embodiment, the amount is 700 k.i.u./liter. In another embodiment, the amount is 1500 k.i.u./liter. In another embodiment, the amount is 3000 k.i.u./liter. In another embodiment, the amount is 4000 k.i.u./liter. In another embodiment, the amount is 5000 k.i.u./liter.

Each amount of protease inhibitor represents a separate embodiment of the present invention.

In another embodiment, the protease targeted by the protease inhibitor of methods and compositions of the present invention is a serine protease. In another embodiment, the protease is trypsin. In another embodiment, the protease is chymotrypsin. In another embodiment, the protease is carboxypeptidase. In another embodiment, the protease is aminopeptidase. In another embodiment, the protease is any other protease that functions in the duodenum or the small intestine. Each possibility represents a separate embodiment of the present invention.

The mesenchymal stem cell population of methods and compositions of the present invention is, in another embodiment, an adult mesenchymal stem cell population. In another embodiment, the mesenchymal stem cell population is a juvenile mesenchymal stem cell population. In another embodiment, the mesenchymal stem cell population is an infantile mesenchymal stem cell population. In another embodiment, the mesenchymal stem cell population is a fetal mesenchymal stem cell population. In another embodiment, the mesenchymal stem cell population is a human mesenchymal stem cell population. In another embodiment, the mesenchymal stem cell population is from any animal known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the cell type of interest is a stem cell. In another embodiment, the cell type of interest is a haematopoietic stem cell. In another embodiment, the cell type of interest is an adipocyte. In another embodiment, the cell type of interest is an endothelial progenitor cell. In another embodiment, the cell type of interest is a neural stem cell. In another embodiment, the cell type of interest is an adult tissue-residing progenitor cell. In another embodiment, the cell type of interest is an adult tissue-residing pancreatic progenitor cell. In another embodiment, the cell type of interest is a regenerating native beta-cell. In another embodiment, the cell type of interest is a gastrointestinal stem cell. In another embodiment, the cell type of interest is a hepatopancreatic epithelial stem cell. In another embodiment, the cell type of interest is an epidermal stem cell. In another embodiment, the cell type of interest is an intestinal epithelial stem cell. In another embodiment, the cell type of interest is a retinal stem cell. In another embodiment, the cell type of interest is a neuronal epithelial stem cell. In another embodiment, the cell type of interest is a muscle stem cell. In another embodiment, the cell type of interest is an endothelial stem cell. In another embodiment, the cell type of interest is a peripheral blood stem cell. In another embodiment, the cell type of interest is any other type of stem cell known in the art.

In another embodiment, the cell type of interest is a progenitor cell. In another embodiment, the cell type of interest is a chondrogenic progenitor cell. In another embodiment, the cell type of interest is an adipogenic progenitor cell. In another embodiment, the cell type of interest is a marrow stroma progenitor cell. In another embodiment, the cell type of interest is a myogenic progenitor cell. In another embodiment, the cell type of interest is an osteogenic progenitor cell. In another embodiment, the cell type of interest is a tendon progenitor cell. In another embodiment, the cell type of interest is any other type of progenitor cell known in the art.

In another embodiment, the cell type of interest is a progeny cell type. In another embodiment, the cell type of interest is a chondrocyte. In another embodiment, the cell type of interest is a stromal cell. In another embodiment, the cell type of interest is a myotube cell. In another embodiment, the cell type of interest is an osteocyte. In another embodiment, the cell type of interest is a tenocyte. In another embodiment, the cell type of interest is any other progeny cell type known in the art.

In another embodiment, a method of the present invention further comprises the step of incubating the mesenchymal stem cells in an induction medium. In another embodiment, the induction medium is a stem cell induction medium. In another embodiment, the induction medium is an osteoblast induction medium. In another embodiment, the induction medium is a haematopoietic stem cell induction medium. In another embodiment, the induction medium is an adipocyte induction medium. In another embodiment, the induction medium is an endothelial progenitor cell induction medium. In another embodiment, the induction medium is a neural stem cell induction medium. In another embodiment, the induction medium is an adult tissue-residing progenitor cell induction medium. In another embodiment, the induction medium is an adult tissue-residing pancreatic progenitor cell induction medium. In another embodiment, the induction medium is a regenerating native beta-cell induction medium. In another embodiment, the induction medium is a gastrointestinal stem cell induction medium. In another embodiment, the induction medium is a hepatopancreatic epithelial stem cell induction medium. In another embodiment, the induction medium is an epidermal stem cell induction medium. In another embodiment, the induction medium is an intestinal epithelial stem cell induction medium. In another embodiment, the induction medium is a retinal stem cell induction medium. In another embodiment, the induction medium is a neuronal epithelial stem cell induction medium. In another embodiment, the induction medium is a muscle stem cell induction medium. In another embodiment, the induction medium is an endothelial stem cell induction medium. In another embodiment, the induction medium is a peripheral blood stem cell induction medium. In another embodiment, the induction medium is any other type of induction medium known in the art.

In another embodiment, the induction medium is a progenitor cell induction medium. In another embodiment, the induction medium is a chondrogenic progenitor cell induction medium. In another embodiment, the induction medium is an adipogenic progenitor cell induction medium. In another embodiment, the induction medium is a marrow stroma progenitor cell induction medium. In another embodiment, the induction medium is a myogenic progenitor cell induction medium. In another embodiment, the induction medium is an osteogenic progenitor cell induction medium. In another embodiment, the induction medium is a tendon progenitor cell induction medium. In another embodiment, the induction medium is any other type of progenitor cell known in the art.

In another embodiment, the induction medium is any other type of induction medium known in the art. Each possibility represents a separate embodiment of the present invention.

The step of culturing of methods and compositions of the present invention is performed, in another embodiment, for at least 5 days. In another embodiment, the step of culturing is performed for at least 4 days. In another embodiment, the step of culturing is performed for at least 6 days. In another embodiment, the step of culturing is performed for at least 7 days. In another embodiment, the step of culturing is performed for at least 8 days. In another embodiment, the step of culturing is performed for at least 10 days. In another embodiment, the step of culturing is performed for at least 12 days. In another embodiment, the step of culturing is performed for at least 15 days. In another embodiment, the step of culturing is performed for at least 20 days. In another embodiment, the step of culturing is performed for at least 25 days. In another embodiment, the step of culturing is performed for at least 30 days. In another embodiment, the step of culturing is performed for at least 35 days. In another embodiment, the step of culturing is performed for at least 40 days. In another embodiment, the step of culturing is performed for at least 50 days. In another embodiment, the step of culturing is performed for at least 60 days. In another embodiment, the step of culturing is performed for over 4 days. In another embodiment, the step of culturing is performed for over 6 days. In another embodiment, the step of culturing is performed for over 7 days. In another embodiment, the step of culturing is performed for over 8 days. In another embodiment, the step of culturing is performed for over 10 days. In another embodiment, the step of culturing is performed for over 12 days. In another embodiment, the step of culturing is performed for over 15 days. In another embodiment, the step of culturing is performed for over 20 days. In another embodiment, the step of culturing is performed for over 25 days. In another embodiment, the step of culturing is performed for over 30 days. In another embodiment, the step of culturing is performed for over 35 days. In another embodiment, the step of culturing is performed for over 40 days. In another embodiment, the step of culturing is performed for over 50 days. In another embodiment, the step of culturing is performed for over 60 days. In another embodiment, the step of culturing is performed for 4 days. In another embodiment, the step of culturing is performed for 6 days. In another embodiment, the step of culturing is performed for 7 days. In another embodiment, the step of culturing is performed for 8 days. In another embodiment, the step of culturing is performed for 10 days. In another embodiment, the step of culturing is performed for 12 days. In another embodiment, the step of culturing is performed for 15 days. In another embodiment, the step of culturing is performed for 20 days. In another embodiment, the step of culturing is performed for 25 days. In another embodiment, the step of culturing is performed for 30 days. In another embodiment, the step of culturing is performed for 35 days. In another embodiment, the step of culturing is performed for 40 days. In another embodiment, the step of culturing is performed for 50 days. In another embodiment, the step of culturing is performed for 60 days. In another embodiment, the step of culturing is performed for at over 60 days. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the step of culturing the mesenchymal stem cell population in a gel or matrix of the present invention is preceded by a step of culturing the mesenchymal stem cells in a tissue culture apparatus. In another embodiment, the tissue culture apparatus is a dish. In another embodiment, the tissue culture apparatus is a plate. In another embodiment, the tissue culture apparatus is a flask. In another embodiment, the tissue culture apparatus is a bottle. In another embodiment, the tissue culture apparatus is a tube. In another embodiment, the tissue culture apparatus is any other type of tissue culture apparatus known in the art. In another embodiment, the step of culturing is preceded by a step of culturing the mesenchymal stem cells in tissue-culture media; e.g. not in the presence of a gel or matrix of the present invention. In another embodiment, the step of culturing the cells in a tissue culture apparatus or in tissue culture media is performed after isolation of the mesenchymal stem cell population from a biological sample. In another embodiment, the step of culturing is performed after purification of the mesenchymal stem cell population from a biological sample. In another embodiment, the step of culturing is performed after enrichment of the mesenchymal stem cell population in a biological sample. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the step of culturing the mesenchymal stem cell population in a gel or matrix of the present invention is performed directly after isolation of the mesenchymal stem cell population from a biological sample. In another embodiment, the step of culturing is performed directly after purification of the mesenchymal stem cell population from a biological sample. In another embodiment, the step of culturing is performed directly after enrichment of the mesenchymal stem cell population in a biological sample. “Directly” refers, in another embodiment, to a culturing step in the absence of culturing first in a tissue culture apparatus. Each possibility represents a separate embodiment of the present invention.

The progenitor cell population of methods and compositions of the present invention is, in another embodiment, a hematopoietic stem cell population. In another embodiment, the progenitor cell population is an endothelial cell precursor population. In another embodiment, the progenitor cell population is a satellite cell population (e.g. muscle cell precursors). In another embodiment, the progenitor cell population is a population of transit-amplifying neural progenitors of the rostral migratory stream. In another embodiment, the progenitor cell population is a bone marrow stromal cell population. In another embodiment, the progenitor cell population is any other progenitor cell population known in the art. Each possibility represents a separate embodiment of the present invention.

“Progenitor cell population” refers, in another embodiment, to a population comprising progenitor cells. In another embodiment, the population is enriched for progenitor cells. In another embodiment, the population is a partially purified progenitor cell population. In another embodiment, the progenitor cells are isolated from a biological source, followed by a purification or enrichment step. In another embodiment, isolation from the biological source is followed by culturing. In another embodiment, isolation from the biological source is followed by culturing and a purification or enrichment step. Each possibility represents a separate embodiment of the present invention.

In another embodiment, provided herein is a method of differentiating a transformed cell into a differentiated cell type, comprising the step of culturing the transformed cell in a gel or matrix of the present invention, thereby differentiating a transformed cell into a differentiated cell type. In another embodiment, the differentiated cell type is a progenitor cell. In another embodiment, the differentiated cell type is a progeny cell type. In another embodiment, the differentiated cell type is a tissue cell type. In another embodiment, the differentiated cell type is one of the above cell types. In another embodiment, the differentiated cell type is any other type of differentiated cell type known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a cell or cell population prepared by a method of the present invention is used for replacement of damaged tissues in a subject. In another embodiment, a cell or cell population prepared by a method of the present invention is used as carrier for anti-cancer agents (Kassem M, Ann N Y Acad. Sci. 2006 May; 1067:436-42). Each possibility represents a separate embodiment of the present invention.

Methods for determining proliferative capacity and differentiation potency of mesenchymal stem cells are well known in the art, and are described, for example, in Baxter M A et al (Study of telomere length reveals rapid aging of human marrow stromal cells following in vitro expansion. Stem Cells. 2004; 22(5):675-82), Liu L et al (Telomerase deficiency impairs differentiation of mesenchymal stem cells. Exp Cell Res. 2004 Mar. 10; 294(1):1-8), and Bonab M M et al (Aging of mesenchymal stem cell in vitro. BMC Cell Biol. 2006 Mar. 10; 7:14). Each possibility represents another embodiment of the present invention.

In another embodiment, an advantage of methods and compositions of the present invention is the lack of immortalization of mesenchymal stem cells. In another embodiment, an advantage is lack of evolution of cancer cells from a mesenchymal stem cell population. In another embodiment, an advantage is retention of ability of the target cells to differentiate into multiple cell types. In another embodiment, an advantage is retention of proliferative capacity of the cells. In another embodiment, an advantage is retention of ability of the cells to support hematopoietic cell growth. In another embodiment, an advantage is ability of the target cells to differentiate without a requirement for contact inhibition. In another embodiment, the differentiation is a consequence of inhibition of proliferation. Each possibility represents another embodiment of the present invention.

In one embodiment, provided herein are methods for inducing proliferation of a quiescent somatic stem cell. It has been discovered that contacting a stem cell with a material that is less elastic than the elasticity of the naturally occurring in vivo microenvironment of the same type of stem cell is effective to induce proliferation of the stem cell. Embodiments of the present invention thus include contacting the somatic stem cell with a material that comprises compounds that attaches to integrins on the surface of the cell membrane and that has elasticity apparent to the stem cell less than the elasticity of the predominant material in the biological microenvironment of an in vivo somatic stem cell of the same type as the somatic stem cell. For example, the proliferation of quiescent stem cells may be induced by placing them on a glass slide, which has a rigidity of more than 1 gigaPascal (a small fraction of the elasticity of most human or animal tissue types) and which is coated with a material contacting the integrins on the cell. In other embodiments, proliferation of a stem cell may be induced by contacting the cell with a material apparent to the cell having an elasticity of less than 0.1 of the elasticity of the natural in vivo microenvironment of the stem cell. In other embodiments, proliferation may be induced by contacting the stem cell with a material having an elasticity apparent to the stem cell of less than about 0.5 times (e.g., about 0.4 to about 0.5 times) the elasticity of the natural in vivo microenvironment of the stem cell.

In embodiments, the cell may also be provided with nutrient-growth material, for example, including growth factors and serum, for promoting proliferation and sustaining biological activity of the stem cell and its progeny ex vivo. The formulation of the nutrient-growth material for particular cell types is known to those of skill in the art, and no variation in known nutrient-growth materials for particular types of stem cells should be needed to practice this aspect of the present invention.

As with other aspects of the present invention, embodiments of this proliferation-inducing aspect may be practiced with stem cells, including MSCs. The MSCs may be harvested from living tissue, as described in this specification, or derived from other sources such as in vitro cultures and cryogenically frozen stem cells. Such cells may be in a naturally-occurring quiescent state or an artificially-induced quiescent state, and may for example include cells in which quiescence has been induced or maintained using methods of the present invention. Accordingly, cells in which proliferation may be induced according to methods of the present invention may include bone marrow-derived mesenchymal stem cells (MSCs), renal stem cells, hepatic stem cells, skeletal muscle-derived stem cells, bone-derived stem cells, dental pulp MSCs, cardiac muscle-derived MSCs, synovial fluid-derived MSCs, umbilical cord MSCs, and other types of cells that can be identified by one of skill in the art in light of this specification.

The proliferation of stem cells according to the present invention is reversible, enabling alternating states of quiescence and proliferation to be induced into a cell. For example, the methods of the present invention may be used to induce and maintain quiescence in a stem cell, for example by contacting the stem cell with a material comprising compounds that bind to integrins on the cell surface and having elasticity apparent to the cell approximately the same as the elasticity of the in vivo microenvironment of the cell. Then proliferation may be induced in the cell by contacting the cell with a material comprising compounds that attach to integrins and having elasticity apparent to the cell substantially less than the elasticity of the in vivo microenvironment of the cell. Then quiescence may be induced and maintained by contacting the resulting daughter cells with a material including integrin-binding compounds and having elasticity apparent to the cells approximately the same as the in vivo microenvironment of the cells.

In another embodiment, proliferating stem cells are induced into a quiescent state according to a method of the present invention. These quiescent cells may then be induced to proliferate, as described above.

The present invention further provides methods for inducing differentiation of a somatic stem cell in which biological activity is being sustained and quiescence has been induced or is being maintained according to the methods of the present invention. Embodiments of this aspect of the present invention include the step of contacting such cells with a differentiation material comprising chemical stimuli selected to stimulate differentiation of the cells to a predetermined cell type, and providing the cells with a differentiated cell nutrient material for sustaining biological activity of the differentiation-stimulated cells. In some embodiments, the contacting step may be preceded by a step comprising inducing (or permitting) proliferation, for example ex vivo, of the somatic stem cell by contacting the stem cell with a material having elasticity less than the elasticity of the natural microenvironment of the target cell of intended differentiation.

Differentiation may be induced in quiescent or proliferating stem cells sustained in biological activity according to this invention, using methods known or apparent to those of skill in the art in light of this specification. For example, if the stem cell is a human bone marrow-derived mesenchymal stem cell, differentiation of the cell into adipocytes may be effectuated by contacting the cell with an adipogenic medium (as discussed in Example 1) on a substrate with an elasticity of approximately 250 Pa, as described in detail in this specification. Using information that may be obtained from or as described in this specification concerning the rheology of various tissue types as well as the differentiation medium to be used to induce stem cells to differentiate into various types of cells, it would be apparent to those of skill in the art that methods of the present invention may be used to induce a human bone marrow-derived mesenchymal stem cell to differentiate into one or more of at least the following cell types: osteoblasts, chondrocytes, myocytes, adipocytes, beta-pancreatic islet cells, and neuronal cells. More generally, using information on rheology of various tissue types and differentiation media used to induce differentiation of various stem cell types into various types of cells, it would be readily apparent to those of skill in the art to induce differentiation, in any of the stem cell types identified in this specification, into one or more of an osteoblast, a chondrocyte, a myocyte, an adipocyte, a beta-pancreatic islet cell, a neuronal cell, or another cell type.

In embodiments of this aspect of the invention, the differentiated cells are contacted with a medium including nutrients to maintain biological activity of the cells. For example, if a method of the present invention is used to induce a human bone marrow-derived mesenchymal stem cell to differentiate into adipocytes, the resulting adipocytes may be contacted with a nutrient medium in order to sustain their biological activity. The nutrient medium may comprise DMEM (low glucose), fetal bovine serum, and insulin. Other nutrient media, and methods for contacting differentiated cells with them, will be apparent to those of skill in the art in light of this specification.

The present invention further provides an artificial system for inducing or maintaining quiescence and sustainable biological activity of a somatic stem cell. In embodiments, the system includes an extracellular material (ECM) ligand substance for contacting a stem cell, a substrate material linked to the ECM ligand substance, and a medium for providing nutrients to the stem cell and sustaining its biological activity. The ECM ligand substance, when linked to the substrate material, has elasticity similar to the elasticity of the predominant in vivo material in the biological microenvironment of an in vivo stem cell of the same type. Embodiments of the system may be adapted to induce quiescence in any of the cell types in which quiescence may be induced according to the methods of the invention described in this specification. For example, embodiments of the system may be adapted to induce quiescence in a somatic stem cell or an embryonic stem cell, a human stem cell or an animal stem cell, a mesenchymal somatic stem cell (MSC), a bone marrow-derived MSCs, a renal stem cell, a hepatic-derived stem cell, a skeletal muscle-derived MSC, a bone-derived MSC, a dental pulp MSC, a cardiac muscle-derived MSC a synovial-fluid derived MSC or an umbilical cord MSC.

In embodiments, when the ECM ligand substance is linked to the substrate and contacts a stem cell, the ECM material binds to integrins on the surface of the stem cell in a manner that induces the stem cell to enter quiescence, as described in detail in this specification.

In embodiments of such a system of the present invention, there may be a linking material that links the ECM ligand material with the substrate material. For example, when the substrate material comprises a polyacrylamide gel and the ECM comprises a collagen-fibronectin mixture, the linking material may be NHS, including specifically acrylic acid N-hydroxysuccinimide ester. Depending on the nature of the substrate material and the extracellular material, those of skill in the art can readily ascertain linking materials, which may also be characterized as cross-linkers, to be used to link the substrate material and the ECM in various embodiments of systems of the present invention.

In embodiments of the present invention, when the ECM ligand layer is coupled to the substrate, the ECM ligand layer has elasticity apparent to the stem cell substantially similar to the elasticity of the predominant material in the biological microenvironment of an in vivo stem cell of the same type as the stem cell contacting the ECM ligand layer. This apparent elasticity of the ECM ligand layer may be independent of, nearly independent of, or dependent on the elasticity of the substrate. In embodiments, the elasticity of the substrate is substantially similar to the elasticity of the predominant material in the biological microenvironment of an in vivo stem cell of the same type as the stem cell contacting the ECM ligand layer, and the ECM ligand layer presents to the stem cell substantially the same elasticity as the elasticity of the substrate to which it is coupled.

The artificial system of the present invention may be implemented using a variety of structures. In embodiments, the substrate material forms a matrix, and the ECM is dispersed in the matrix. In embodiments, a linking material may also be dispersed in the substrate matrix for linking the material of the substrate matrix with the ECM. For example, according to one embodiment, a 5:1 mixture of collagen derived from rat tails (0.5 mg/ml) and fibronectin derived from humans (0.1 mg/ml), and an acrylic acid N-hydroxysuccinimide ester (NHS) cross-linker, are dispersed in a polyacrylamide gel. The gel is formulated so that the elasticity of the structure is about 250 Pa. When bone marrow-derived MSCs are contacted with the polyacrylamide-NHS-fibronectin-collagen structure, they are induced to enter quiescence. When the MSCs contacting the structure are also provided with suitable nutrient material, their biological activity in a quiescent state is maintained.

In embodiments, the substrate material forms a layer, and the ECM forms a layer linked, directly or indirectly, with the substrate layer. In other embodiments, the linking material forms a linking layer that links the ECM ligand layer with the substrate layer. The linking layer may serve to present the elasticity of the substrate to the ECM ligand layer in a manner that enables the ECM ligand layer to present that elasticity to the stem cell in which quiescence is to be induced. In an embodiment, the linking layer includes appropriate cross-linking compositions and other materials that serve these functions. For example, the coupling layer may comprise NHS or, in specific embodiments, acrylic acid N-hydroxysuccinimide ester.

In embodiments, the substrate material is a polyacrylamide gel. As is known in the art, the elasticity of polyacrylamide gels may be adjusted by changing the concentrations of acrylamide and bisacrylamide in the gel. It would be apparent to those of skill in the art, in light of this specification, how to make polyacrylamide or other gels or substrate materials for use in the systems of the present invention.

As is further apparent in light of this specification, embodiments may utilize other structures. For example, a quasi 3-D structure may be created by seeding stem cells on an ECM layer as described above, settling the cells onto the ECM layer by submerging the system with cells in medium, and placing on the cells another ECM layer with appropriate apparent elasticity, as described further in Example 1.

In another embodiment, an advantage of methods and compositions of the present invention is resistance of the matrix or gel to proteolytic degradation. In another embodiment, an advantage is resistance to active remodeling by the cells. In another embodiment, an advantage is resistance of heterothermic (e.g. salmon) fibrin to proteases secreted by mammalian neurons compared to mammalian (e.g. human or bovine) fibrin. In another embodiment, an advantage is lower incidence of infectious disease transfer of heterothermic (e.g. salmon) fibrin compared to mammalian (e.g. human or bovine) fibrin. Each possibility represents another embodiment of the present invention.

In another embodiment, the target cell of methods and compositions of the present invention is an immortalized MSC.

In another embodiment, provided herein is a method of inducing growth arrest of an immortalized MSC, comprising the step of culturing the immortalized MSC in a gel or matrix of the present invention, thereby inducing growth arrest of an immortalized MSC. In another embodiment, provided herein is a method of inhibiting growth of an immortalized MSC population, comprising the step of culturing the immortalized MSC in a gel or matrix of the present invention, thereby inhibiting growth of an immortalized MSC population. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the target cell of methods and compositions of the present invention is a transformed cell. In another embodiment, the transformed cell is a melanoma cell. In another embodiment, the transformed cell is any other type of transformed cell known in the art. Each possibility represents a separate embodiment of the present invention.

As provided herein, M2 cells exhibited a larger size and larger cell population on stiffer substrates. In another embodiment, an increased cell population is a result of increased growth of the cells on stiff substrates. In another embodiment, an increased population is due to increased death of cells on soft substrates. Each possibility represents a separate embodiment of the present invention.

In another embodiment, provided herein is a method of inducing growth arrest of a transformed cell, comprising the step of culturing the transformed cell in a gel or matrix of the present invention, thereby inducing growth arrest of a transformed cell. In another embodiment, provided herein is a method of inhibiting growth of a transformed cell population, comprising the step of culturing the transformed cell in a gel or matrix of the present invention, thereby inhibiting growth of a transformed cell population. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a soft substrate of methods and compositions of the present invention results in an increase in inactive GDP-bound form of a GTP protein in the target cells. In another embodiment, the GTP protein is Rho. In another embodiment, the GTP protein is Rac. In another embodiment, the GTP protein is Cdc42. In another embodiment, the GTP protein is any other GTP protein known in the art. Each possibility represents a separate embodiment of the present invention.

In another embodiment, the Rho family member signals via formation of focal adhesions. In another embodiment, activation of Rho inhibits expression of p21^(WAF1/clp1). In another embodiment, inhibition of p21 activates cyclin-dependent kinases (CDKs). In another embodiment, activation of Rho induces downregulation and degradation of p27^(Klp2), another CDK inhibitor. In another embodiment, activation of Rho induces ROCK, resulting in activation of the Ras-Raf-MEK-ERK pathway. In another embodiment, this pathway induces Ras-mediated cyclin-D1 transcription. In another embodiment, this induces G1-phase progression. Together, Rho activation was shown to lead to G1-phase progression. In another embodiment, activation of Rac or Cdc42 upregulates cyclin-E1 and cyclin-D1, resulting in G1-phase progression. In another embodiment, activation of a Rho-family small GTP-binding protein results in signal transduction to enhance cell cycle progression. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a soft substrate of methods and compositions of the present invention decreases the contractility of the actomyosin system of the target cell. In another embodiment, this induces target cells to cease proliferation. In another embodiment, this induces target cells to become competent for further stimuli to re-initiate proliferation. In another embodiment, this induces target cells to become competent for further stimuli to commit to terminal differentiation. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a soft substrate of methods and compositions of the present invention induces activation of actomyosin. In another embodiment, the soft substrate induces actomyosin regulated by Rho. In another embodiment, the soft substrate induces myosin II. In another embodiment, the soft substrate induces myosin II regulated by Rho. Each possibility represents a separate embodiment of the present invention.

In another embodiment, a composition of methods and compositions of the present invention further comprises an activator of a Rho family member. In another embodiment, the composition further comprises an inhibitor of a Rho family member. In another embodiment, the Rho family member is Rho. In another embodiment, the Rho family member is Rac. In another embodiment, the Rho family member is Cdc42. In another embodiment, the Rho family member is any other Rho family member known in the art. Each possibility represents a separate embodiment of the present invention. In another embodiment, the composition further comprises an activator of actomyosin. In another embodiment, the composition further comprises an inhibitor of actomyosin. In another embodiment, the composition further comprises an activator of myosin II. In another embodiment, the composition further comprises an inhibitor of myosin II. Each possibility represents a separate embodiment of the present invention.

Methods for polymerizing acrylamide gels are well known in the art. In another embodiment, 1.5 μl TEMED (FisherBiotech CAS no. 110189) and 5 μl 10% ammonium persulfate are added with the appropriate amount of H₂O to yield a final volume of 1,000 μl, the solution is pipetted onto a cover slip, and a top cover slip is placed on top of the solution, then peeled away 10 minutes later. Each method represents a separate embodiment of the present invention.

In another embodiment, to crosslink adhesion proteins onto the gel or matrix, a heterobifunctional crosslinker is utilized. In another embodiment, the heterobifunctional crosslinker is sulfo-SANPAH (sulfosuccinimidyl6(4′-azido-2′-nitrophenyl-amino)hexanoate, Pierce no. 22589). In another embodiment, the heterobifunctional crosslinker is any other heterobifunctional crosslinker known in the art. In another embodiment, sulfo-SANPAH is used as follows. 1 mg/ml sulfo-SANPAH is dissolved in H₂O, and 200 μl of this solution is pipetted onto the gel surface. The polyacrylamide gel is then placed 6 inches under an ultraviolet lamp and irradiated for 10 mM. It is then washed three times each with 3 mL of 200 mM HEPES, pH 8.6. After the last HEPES solution is aspirated, 200 μl of a 0.14 mg/ml fish fibronectin solution (Sea Run Holdings, South Freeport, Me.) or 0.14 mg/ml type I collagen is pipetted on top of the polyacrylamide gel. The multiwell plate housing the gels is then incubated at 5° C. for 4 h. Each method represents a separate embodiment of the present invention.

In another aspect of the present invention, a kit of components may be provided for assembling a system as described above or for otherwise carrying out the methods of the present invention. In an embodiment, such a kit includes as separate components: (1) a substrate, or materials for making a substrate; (2) optionally materials for making and/or applying a coupling layer; and (3) materials for making and/or applying ECM ligand material to form an ECM ligand layer. The substrate component may, for example, comprise a polyacrylamide gel of a predetermined elasticity, a polyacrylamide gel with materials for adjusting the elasticity of the gel to a predetermined elasticity or range of elasticities, or materials for making a gel or other suitable substrate with the desired elasticity. In embodiments, the kit includes a device for mounting or holding the gel in order to facilitate the application of the ECM ligand layer and optionally a coupling layer for coupling the substrate to the ECM ligand layer. As is apparent to those of skill in the art in light of this specification, various components of the kits of this invention may be combined in order to facilitate storage, shipment and assembly of the kits.

Embodiments of such a kit also may include materials for making and/or applying the ECM ligand layer. For example, the kit may include ECM ligand material for direct application to the substrate. In other embodiments, the kit may include individual components or ingredients of the material of the ECM ligand layer, with instructions for making and applying it to the other components of the kit. Optionally, the kit may include materials and instructions for assembling and applying a coupling layer for coupling the substrate to the ECM ligand layer. In a specific embodiment, a kit of a system of the present invention for inducing quiescence in a human bone marrow-derived MSC includes the following:

(a) a glass Petri dish (or other apparatus for supporting the substrate and holding the rest of the components);

(b) materials for making a polyacrylamide gel with about 250 Pa hardness to serve as the substrate, including appropriate amounts of acrylamide and bisacrylamide;

(c) acrylic acid N-hydroxysuccinimide ester (NHS) cross-linker for applying to the gel in order to form a coupling layer; and

(d) materials for making an ECM ligand layer, including the materials identified in Example 1, for making a 1:5 fibronectin-collagen extracellular material.

In an embodiment, a kit of the present invention comprises a polyacrylamide gel formulated with an elasticity for inducing quiescence in stem cells of a specified type; a solution including cross-linking compositions for application to the gel; extracellular material formulated to bind to integrins on the surface of the specified type of cells; and, optionally, suitable nutrient material (which may also be prepared by users) for the cells to be induced into quiescence.

In some embodiments of the kit, the kit comprises one layer of material that provides both elasticity and ECM ligands. In another embodiment, the kit may comprise the following three layers of materials:

a) a gel substrate that confers elasticity to the system;

b) ECM ligands; and

c) crosslinkers that connect ECM ligands to the substrate.

In embodiments of kits of the present invention, the components of the kit are placed in a receptacle such as a bag or plastic package containing phosphate-buffered saline (PBS). In some embodiments, the receptacle may also contain preservatives such as sodium azide. The components may be hydrated in the kit, for example, during storage. In some embodiments, the receptacle is sealed and/or protected with appropriate scaffolds to avoid damage to the system. The kit may be shipped at low temperature, such as about 2° C. to about 8° C.

In embodiments of kits of the present invention, users can open the receptacle and place the components of the kit onto an appropriate material, such as a tissue culture plate. Users can also remove any hard material on top of the components to expose the ECM ligands and wash the components with a buffer such as PBS. Users can then seed cells onto the system by putting a cell suspension that comprises cells, medium, and serum, as necessary.

The systems and methods of the present invention may be practiced in vivo as well as ex vivo. Such systems may, for example, include porous structures for insertion in specific tissues or the circulatory system for maintaining a stem cell in quiescence within the body. For example, stem cells, corresponding ECM and, optionally, linking material, may be dispersed in a polymeric matrix that has appropriate elasticity apparent to the stem cells to induce or maintain quiescence, and that also has sufficient porosity to permit in vivo nutrients to reach the cell and to permit proteins and other factors expressed by the cell to leave the matrix. Other embodiments may include cassettes or other devices that induce or maintain quiescence in stem cells, and that may be implanted into a host.

A further aspect of the present invention encompasses a quiescent stem cell sustained in biological activity ex vivo. Examples of such a stem cell include a somatic stem cell or an embryonic stem cell, a human stem cell or an animal stem cell, a mesenchymal stem cell (MSC), a bone marrow-derived MSCs, a renal stem cell, a hepatic-derived stem cell, a skeletal muscle-derived MSC, a bone-derived MSC, a dental pulp MSC, a cardiac muscle-derived MSC a synovial-fluid derived MSC or an umbilical cord MSC. In embodiments, the systems or methods of the present invention are used to induce or maintain a stem cell in a quiescent state, and to sustain the biological activity of such quiescent stem cells.

Accordingly, in one embodiment, provided herein is an apparatus for modulating growth of a mesenchymal stem cell comprising: a gel matrix having a rigidity in a range of 150-750 Pa; and an adipocyte induction medium, wherein said gel or matrix is coated with a type I collagen, a fibronectin, or a combination thereof.

In other embodiments, the gels and matrices of any of the methods described above have any of the characteristics of a gel or matrix of compositions of the present invention. Each characteristic represents a separate embodiment of the present invention.

EXPERIMENTAL DETAILS SECTION Example 1: Measurement of the Rigidity of Various Tissues and Preparation of Polyacrylamide Gels Approximating the Rigidities of the Tissues Materials and Experimental Methods

Preparation of Polyacrylamide Gels

Acrylamide and bisacrylamide (Fisher Biotech, Loughborough, Leicestershire, UK) solutions were prepared to contain a constant polymer mass of 7.5% and bisacrylamide concentrations of 0.01%, 0.03% or 0.3% to alter stiffness. Acrylamide, bisacrylamide, ammonium persulfate, and N,N,N′,N′-tetramethylethylenediamine (TEMED) under a nonaqueous layer of toluene containing 0.5% acrylic acid N-hydroxy succinimide ester (Sigma, St. Louis, Miss.) was polymerized between two coverslips, chemically modified as follows: 200 μl of 0.1 N NaOH was pipetted to cover the surface of a 25-mm-diameter glass cover slip (Fisherbrand, catalog no. 12-545-102; Fisher Scientific, Pittsburgh, Pa.) for 5 min. The NaOH solution was aspirated, and 200 μl of 3-APTMS (3-Aminopropyltrimethoxysilane, Sigma no. 28-1778, Sigma, St. Louis, Mo.) was applied for 3 min. The glass cover slip was thoroughly rinsed with de-ionized water to wash away any remaining 3-APTMS solution, and 200 μl of 0.5% v glutaraldehyde (Sigma no. G7651) in H₂O was added onto the cover slip for 20 min. The glass cover slip was rinsed with water, an 18-mm-diameter glass cover slip was placed on top of a piece of parafilm inside a tissue culture dish, and a few drops of a 10% by volume Surfasil solution (Pierce no. 42800, Pierce, Rockford, Ill.) in chloroform was pipetted onto the parafilm near the cover slip. The tissue culture dish with a half-closed lid was placed inside a vacuum desiccator for 10 min.

The N-succinimidyl acrylate incorporated at the surface of the gel was reacted with 0.2 mg/ml laminin (Collaborative Biomedical, Bedford, Mass.) to produce a uniform coating of adhesive ligands. After washing with HEPES buffer to remove traces of un-polymerized solvent, wells containing the polyacrylamide (PA) gels were filled with culture medium and allowed to equilibrate overnight at 37° C.

Viscoelastic Characterization of Material Scaffolds

The dynamic shear moduli of gels were measured on a strain-controlled rheometrics fluids spectrometer III (Rheometrics, Piscataway, N.J.). A 500-μL sample was polymerized between two steel plates, and the shear modulus G′(ω), which describes elastic resistance, was calculated from the shear stress in phase with a 2% oscillatory (1 rad/s) shear strain. The dynamic shear moduli of tissues were similarly measured. An 8-mm diameter sample was cut using a stainless steel punch and placed between the plates. Short-term G′(ω) was measured by oscillation at 2% strain and the long-term shear modulus G(t) was measured by applying a 10% steady strain and allowing the sample to relax for 30 s.

Results

Polyacrylamide gels were prepared and coated with a mixture of 0.14 mg/ml type I collagen and 0.14 mg/ml fish fibronectin. By adjusting the concentration of acrylamide and bisacrylamide, a wide range of rigidity was achieved (FIG. 1A). The rigidity of polyacrylamide gels does not affect the amount and the distribution of the extracellular matrix on gels. In vitro rheometry was also used to determine the elastic properties of tissues relevant to mesenchymal stem cells (Table 1). Polyacrylamide gels with G′ of 200 Pa (herein used as one example of “soft gels” and referred to as such) or 7500 Pa (herein used as one example of “stiff gels” and referred to as such) were prepared; the soft gels mimic the rigidity of bone marrow and fat tissues.

TABLE 1 Rigidity of tissues. Tissue Rigidity (Pa) bovine bone marrow 225 ± 25 rat subcutaneous fat 157 ± 36 rat visceral fat 130 ± 40 rat liver 403 ± 28 rat skeletal muscle 2251 ± 166 Rat tissues were obtained from three Sprague-Dawley rats.

Thus, polyacrylamide gels were prepared that mimic the rigidity of biological tissue.

Example 2: Cell Shape and F-Actin Structure of hMSC on Soft and Stiff Gels Materials and Experimental Methods

hMSC were sparsely seeded on either stiff gels or soft gels coated with collagen type 1 and fibronectin. Cells were incubated for 24 hours in DMEM+10% fetal calf serum, fixed, and stained with Alexa Fluor 488 phalloidin.

Results

The effect of extracellular matrix rigidity on the shape and F-actin structure of hMSC (human mesenchymal stem cells) was investigated. Cells were incubated in the presence of serum on matrices with various rigidities for 24 hours to allow adherence and spreading. hMSC seeded on stiff gels or glass adopted a spindle shape and exhibited stress fibers and cortical F-actin (as shown by Alexa Fluor 488 phalloidin staining), whereas cells seeded on soft gels exhibited a rounded appearance, lacked stress fibers, and contained F-actin aggregates (FIG. 1B-C).

Thus, hMSC sense the rigidity of the extracellular matrix, which influences their shape and F-actin structure.

Example 3: Inhibition of hMSC Proliferation on Soft Gels Materials and Experimental Methods

hMSC were incubated with BrdU (Invitrogen, Carlsbad, Calif.) overnight in the presence of serum. Cells were fixed and immunostained for BrdU (Invitrogen). More than 50 cells were counted for three times in randomly chosen fields

Results

5-bromo-2′-deoxyuridine 5′-triphosphate (BrdU) incorporation was measured in hMSC as a marker of cell cycle progression (FIG. 2). Cells were seeded sparsely on soft gels, stiff gels or glass surfaces, all of which were coated with collagen type 1 and fibronectin. As a control, confluent cells on glass surface were also prepared. As expected, hMSC sparsely seeded on glass surfaces efficiently incorporated BrdU, indicating a high level of proliferation. When cells were confluent on glass surface, very few hMSC incorporated BrdU due to a contract inhibition. 42% of hMSC on stiff gels incorporated BrdU, indicating a large population of cells was proliferating, although significantly less than that of sparsely seeded cells on a glass surface. On the other hand, no hMSC on soft gels incorporated BrdU, even though the cells were viable as assessed by lack of Trypan Blue staining. Further, continued incubation of sparsely seeded hMSC on matrices yielded a different cell density depending on the rigidity of matrices with higher density on stiffer matrices.

Thus, soft matrices inhibit proliferation of hMSC even in the presence of serum.

Example 4: hMSC on Soft Gels are Competent to Differentiate into Adipocytes Materials and Experimental Methods

Adipocyte Differentiation Studies

hMSC from cell suspensions were seeded onto collagen type I plus fibronectin-coated 96-well tissue culture plates at a density of 3.5×10⁴ cells/well. After incubating cells in DMEM containing 10% FCS (growth medium, “GM”) for 24 hours, cells were induced to differentiate into adipocytes by incubating 3 for days (2 cell cycles) in Adipogenic Induction Medium (AIM) (GM, 1 μM dexamethasone, 200 μM indomethacin, 10 μg/ml insulin, and 0.5 mM methylisobutylxanthine) then maintaining in Adipogenic Maintenance Medium (GM, 10 (μg/ml insulin). 8 days after switching to AIM, adipocyte differentiation was evaluated either by Oil Red O staining (Sigma-Aldrich, St. Louis, Mo.) or by immuno-staining for PPARγ2 using anti-PPARγ2 antibodies. More than 50 cells were counted for three times in randomly chosen fields. Anti-PPARγ2 antibodies were provided by Dr. Mitchell A. Lazar, University of Pennsylvania.

Results

To confirm the viability of hMSC on soft gels, their ability to differentiate into adipocytes was measured in two ways; (a) immunostaining of peroxisome proliferators-activated receptors gamma 2 (PPARγ2), one of key transcription factors for adipogenesis, and (b) Oil Red O-staining to measure lipid accumulation. When confluent hMSC on a glass surface were induced for adipocyte differentiation by a mixture of dexamethasone, indomethacin, 3-isobutyl-1-methyl-xanthine and insulin in fetal calf serum-containing medium, approximately 40% of cells exhibited an adipocyte phenotype (FIG. 3A). By contrast, on soft gels with induction, the differentiation rate reached more than 80%, significantly higher than on glass; without induction, no adipocyte differentiation was observed. Further, hMSC sparsely seeded on glass exhibited a high level of proliferation (FIG. 2) and did not differentiate into adipocytes (FIG. 3B). These results further indicate that hMSC might need to leave the cell cycle as a prerequisite for terminal differentiation.

Thus, hMSC sparsely seeded on soft gels are fully viable and are competent for adipocyte differentiation.

Example 5: F-Actin Structure in Astrocytes Seeded on Either Stiff or Soft Gels

To further characterize and quantify the response of cells to matrix rigidity, the effect of extracellular matrix stiffness on F-actin structure was also tested in astrocytes. Primary astrocytes were isolated from Sprague-Dawley rat embryos as follows: Embryos (E17-E19) were removed by cesarean section from a timed-pregnant Sprague-Dawley rat and the cortices were removed. Tissue was digested in trypsin/DNase at 37° C., centrifuged (1000 g×5 min), and filtered to derive a cell suspension. For cultures containing both neurons and glial cells, cells were plated directly onto substrates. Primary astrocyte cultures were maintained for 14 days in culture with a series of trypsinizations to remove neurons. Cultures used for experiments were >98% astrocytes as determined by GFAP immunocytochemistry. Cells were grown in an incubator at 37° C. and 5% CO₂ in Dulbecco's modified Eagle's medium (BioWhittaker, East Rutherford, N.J.) supplemented with Ham's F12 (Sigma) and 5% fetal bovine serum (Hyclone, Logan, Utah) for 7 days followed by an additional 5 days culture in Neurobasal (Gibco, Carlsbad, Calif.) also supplemented with 5% fetal bovine serum, 2 mM 1-glutamine, 50 mcg/mL streptomycin, and 50 units/mL penicillin.

Cells were incubated in the presence of serum on either stiff (11 kPa) or soft (150 Pa) polyacrylamide gels for 48 hours to allow adherence and spreading. Cells were fixed, and F-actin structure was visualized with phalloidin. As shown in FIG. 4, stress fibers and cortical F-actin were observed in astrocytes plated on stiff gels. By contrast, in astrocytes plated on soft gels, stress fibers were not present and only cortical actin shells were observed. Thus, astrocytes on soft gels sensed the flexibility of the matrix and consequently did not exhibit stress fibers.

Example 6: Low Level of Rho GTP-Loading in Astrocytes on Soft Gels Materials And Experimental Methods

Rhotekin Pulldown Assay

Cells were washed with ice-cold Tris-buffered saline and lysed in RIPA buffer (50 mM Tris, pH 7.2, 1% Triton X-100, 0.5% sodium deoxycholate, 0.1% SDS, 500 mM NaCl, 10 mM MgCl₂, 10 □g/ml each of leupeptin and aprotinin, and 1 mM PMSF). Cell lysates were clarified by centrifugation at 13 000×g at 4° C. for 10 min, and equal volumes of lysates were incubated with GST-RBD (20 □g) beads at 4° C. for 45 min. Beads were washed 4 times with buffer B (Tris buffer containing 1% Triton X-100, 150 mM NaCl, 10 mM MgCl₂, 10 □g/ml each of leupeptin and aprotinin, and 0.1 mM PMSF). Bound Rho proteins were detected by Western blotting using a monoclonal antibody against RhoA (Santa Cruz Biotechnology). Densitometry analysis was performed using AlphaImager™ system (Alpha Innotech). The amount of RBD-bound Rho was normalized to the total amount of Rho in cell lysates for the comparison of Rho activity (level of GTPbound Rho) in different samples.

Results

To determine whether or not soft gel-induced loss of stress fibers in astrocytes is associated with inactivation of Rho, astrocytes were seeded on polyacrylamide gels with various rigidities and incubated in the presence of serum for 48 hours. Cell lysates were prepared, and GTP-loading of Rho was assayed using purified GST-Rhotekin and a Rhotekin pulldown assay. The ratio of GTP-bound vs. total Rho was calculated. Astrocytes on soft gels exhibited a low level of GTP-bound Rho (FIG. 5), indicating attenuation of Rho activity in astrocytes on a soft matrix, results in absence of stress fibers in the cells.

Example 7: Melanoma Cells Modulate their Spreading, Based on the Rigidity in the Extracellular Matrix Materials and Experimental Methods

M2 cells were sparsely seeded on matrices of various rigidities coated with a mixture of collagen type 1 and fibronectin. After 24 hours of incubation, cell area was measured by tracing cell boundaries. More than 30 cells were counted for 3 times in randomly chosen fields.

Results

To test whether transformed cells modulate their behavior according to the level of rigidity in the extracellular matrix, the effect of rigidity on cell spreading was measured in human melanoma cell lines, termed M2 cells. As shown in FIG. 6, M2 cells exhibited a larger size on stiffer substrates. Thus, transformed M2 cells have an ability to modulate their behavior (for example, cell spreading) according to the mechanical properties of the matrix.

Example 8: Reduced Amount of Melanoma Cells on Soft Gels

To determine the effect of matrix rigidity on the size of M2 cell population, M2 cells were seeded onto soft or stiff gels (the same number on each) and coated with a mixture of type 1 collagen and fibronectin. Efficiency of cell adherence to each substrate was evaluated after 24 hours of incubation in the presence of serum, when M2 cells were fully adhered and spread on both gels. As shown in FIG. 7, there was no significant difference in the number of adhered cells between soft and stiff gels, indicating the matrix rigidity does not affect adherence of M2 cells. After a 72-hour incubation, although the same number of cells adhered to each substrate (FIG. 7), the additional 48 hours of incubation caused a significantly larger cell population on stiff gels (FIG. 8). No noticeable difference in the number of cells floating in the medium was observed between soft and stiff gels after 72 hours of incubation.

These results further demonstrate methods of quantify responses of hMSC to soft substrates.

Example 9: Use of Soft Gels for Long-Term Preservation of hMSC without Attenuating Viability and Self-Renewal Materials and Experimental Methods

Soft polyacrylamide gels with G′ of approximately 200 Pa coated with a mixture of type 1 collagen and fibronectin are prepared on glass coverslips as described for Example 1. Polyacrylamide gels are placed in 6-well plates covered with 1% agarose gel, to avoid cell adhesion outside of polyacrylamide gels, or glass coverslips. 5×10⁴ passage 2 hMSC are seeded either onto soft polyacrylamide gels or directly onto 6-well tissue culture plates coated with type 1 collagen plus fibronectin, and are incubated in DMEM supplemented with 10% fetal calf serum (FCS). Identical hMSC samples are suspended in DMEM containing 10% FCS and 10% dimethylsulfoxide (DMSO) and kept frozen in liquid nitrogen vapor according to conventional protocol (Gordon S L et al, Cryobiology. 2001 September; 43(2):182-7). After reaching 90% confluence, cells that had been plated directly onto tissue culture plates are trypsinized and subcultured in new 6-well tissue culture plates at a density of 5×104 cells/well. Cells on tissue culture plates are maintained until they reach passage 10. Cells plated onto soft polyacrylamide gels are re-fed with fresh DMEM supplemented with 10% FCS twice per 7 days. When hMSC maintained in tissue culture plates reach passage 10, hMSC stocked in liquid nitrogen vapor are thawed to generate a cell suspension.

Results

To determine the viability of hMSC subjected to long-term preservation in a quiescent state in soft gels, hMSC are stored in soft gels until hMSC maintained on tissue culture plates reach passage 10. Viability of these cells is compared with cells stocked in liquid nitrogen vapor. Cells adhered to either soft gels or tissue culture plates are trypsinized, while cells stored in liquid nitrogen are thawed, to generate a cell suspension. Viability is determined by Trypan Blue staining of the cell suspensions. Thus, soft gel storage is an efficacious means of maintaining the viability of hMSC.

To measure the proliferation potency of hMSC stored long-term incubation on soft gels, cells that have been kept on soft gels, on tissue culture plates, or kept frozen in liquid nitrogen vapor are prepared, and a BrdU incorporation assay is conducted by re-plating cells from each source on tissue culture plates coated with type 1 collagen plus fibronectin and incubating in the presence of serum and BrdU for 12 hours. Cells are fixed and immuno-stained for BrdU by incubating cells with anti-BrdU antibodies (Invitrogen).

Example 10: Use of Soft Gels for Long-Term Preservation of hMSC without Attenuating Differentiation Materials and Experimental Methods

Osteoblast Differentiation Assays

Passage 10 hMSC suspensions are seeded onto collagen type 1 plus fibronectin-coated 96-well tissue culture plates at a density of 10³ cells/well. After incubating cells in GM for 24 hours, cells are induced to differentiate into osteoblasts by switching the medium to Osteogenic Induction Medium (OIM) (GM, 50 μM ascorbic acid-2-phosphate, 10 mM p-glycerophosphate, and 100 nM dexamethasone), changing the medium every 3 days for 3 weeks. Osteoblast differentiation is evaluated by fixing the cells with acetone/citrate and staining for alkaline phosphatase activity with Fast Blue RR/naphthol (Sigma-Aldrich, Kit#85).

Results

Next, differentiation potency of hMSC subjected to long-term preservation in a quiescent state in soft gels is measured. hMSC stored on soft gels or tissue culture plates are trypsinized to make generated suspensions; in parallel, cell suspensions are prepared by thawing hMSC kept frozen in liquid nitrogen. Adipocyte differentiation is assessed as described for Example 4.

In additional studies, adipocyte production is measured after incubating hMSC directly on the soft gel, without prior plating in tissue culture dishes and trypsinization.

In additional studies, osteoclast production is measured in cell suspensions prepared from soft gels, tissue culture plates, or frozen storage.

In additional studies, osteoclast production is measured after incubating hMSC directly on the soft gel, without prior plating in tissue culture dishes and trypsinization.

Example 11: Involvement of Rho-Family Small GTP-Binding Proteins and Actomyosin System in Regulating Stem Cell Growth by Matrix Rigidity Materials and Experimental Methods

Rho Family Assays

Polyacrylamide gels with G′ of approximately 200 Pa (soft gels) and with G′ of approximately 7500 Pa (stiff gels) are prepared on glass coverslips, and gels and coverslips are coated with a mixture of type 1 collagen and fibronectin. Polyacrylamide gels or glass coverslips are placed in 6-well plates covered with 1% agarose gel to avoid cell adhesion outside of polyacrylamide gels or glass coverslips. 5×10⁴ hMSC are seeded onto either a polyacrylamide gel or a glass coverslip, then are incubated in the presence of serum for 24 hours. Cells are subjected to a pull-down assay to investigate GTP-loading level of Rho, Rac and Cdc42 by using their Activation Assay Kit (Upstate Biotech, Charlottesville, Va.).

Transfection of Cells with Dominant Negative or Constitutively Active Rho Forms

cDNA for the candidate Rho GTPase is cloned from a rat liver cDNA library, and a mutation creating a D/N- or C/A-form of a Rho protein (Qui R G et al, Proc Natl Acad Sci USA. 1995 Dec. 5; 92(25):11781-5; Lu X et al, Curr Biol. 1996 Dec. 1; 6(12):1677-84) is introduced, and a myc tag-encoding sequence is added to each cDNA. Recombinant adenovirus expressing mutant Rho-family proteins is created and used to overexpress the mutant proteins in hMSC.

Results

To further study the role of Rho-family proteins in transmitting information about the extracellular matrix, activities of Rho-family proteins are assayed in MSC grown in soft or stiff gels. Additional Rho-family proteins involved in transmitting these signals are identified.

In additional experiments, the dominant negative (D/N) form or the constitutively active (C/A) form of a Rho-family protein of interest is overexpressed in hMSC. Recombinant adenovirus expressing LacZ is utilized as a negative control. hMSC from soft gels, stiff gels, or glass coverslips are prepared, incubated for 24 hours, then left uninfected or infected with adenovirus that expresses LacZ or mutant forms of Rho-family proteins. After 36 hours of incubation, BrdU is added to the medium, and cells are incubated for an additional 12 hours in serum-containing medium, then fixed and immunostained for both myc-tag and BrdU by using anti-myc antibodies (Cell Signaling Technology, Danvers, Mass.) and anti-BrdU antibodies (Invitrogen, Carlsbad, Calif.). Comparison of the number of cells positive for BrdU staining between cells uninfected and cells infected with LacZ adenovirus is used to confirm that adenovirus infection itself has no effect on the growth of hMSC. The number of cells positive for BrdU incorporation is compared to the number positive for myc-tag staining. Down-modulation of soft matrix-induced growth arrest or rigid matrix-induced growth promotion by C/A- and D/N-forms of Rho-family proteins, respectively, indicates involvement of the overexpressed Rho-family protein in growth regulation of hMSC by matrix rigidity.

Example 12: Determining the Role of Actomyosin in Regulating Stem Cell Growth by Matrix Rigidity

To study the role of actomyosin in regulating hMSC growth on soft gels before commitment to specific cell lineages, hMSC are seeded on glass coverslips coated with a mixture of collagen type 1 and fibronectin for 24 hours, then are incubated with BrdU in the presence or absence of 20 mM 2,3-butanedione monoxime (BDM), 100 μM blebbistatin or 0.25 μM/ml cytochalasin D (CD) for an additional 12 hours. Throughout the experiment, cells are incubated in the presence of serum. After the incubation, cells are fixed and immuno-stained for BrdU. The effect on hMSC growth of inhibiting myosin II by BDM or bebbistatin, or disrupting actin filaments by CD, is evaluated.

Example 13: Growth and Differentiation of hMSC in Soft 3-Dimensional Fibrin Gels Materials and Experimental Methods

Preparation and Seeding of Fibrin Gels

Salmon fibrinogen (Searun Holdings, Freeport, Me.) is re-hydrated in H₂O and diluted to 3 (for soft gel) or 18 mg/mL (for stiff gel) in 50 mM Tris, 150 mM NaCl, pH 7.4, and 400 microliter (μl) aliquots are polymerized with 2 units/mL of fish thrombin (Searun Holdings) in tissue culture wells. The rigidity of salmon fibrin gels prepared from 3 and 18 mg/mL fibrinogen are 250 Pa and 2150 Pa, respectively. 10⁴ hMSC are mixed with fibrinogen solution in DMEM containing 10% FCS before polymerization, wherein cells are incubated for 24 hours.

Results

Analysis of proliferation of MSC in soft and stiff fibrin gels is evaluated by incubating cells for an additional 12 hours in the presence of serum and BrdU, followed by fixing and immuno-staining for BrdU incorporation.

Differentiation potency of hMSC in fibrin gels is evaluated by efficiency of adipocyte differentiation. MSC in fibrin gels are induced to differentiate into adipocytes by switching the medium to Adipogenic Induction Medium (“AIM” DMEM+10% FBS, 1 micromolar (mcM) dexamethasone, 200 mcM indomethacin, 10 microgram (mcg)/ml insulin, and 0.5 mM methylisobutylxanthine) for 3 days, then maintaining cells in Adipogenic Maintenance Medium (GM, 10 mcg/ml insulin). 8 days after switching to Adipogenic Induction Medium, adipocyte differentiation is evaluated either by Oil Red O staining or by anti-PPARγ2 immunostaining. Percentages of cells positive for Oil Red O staining or PPAR72 staining are compared between soft and stiff fibrin gels.

In other experiments, protease inhibitors are added to the matrix to prevent or inhibit proteolytic degradation or other active remodeling by the cells.

Example 14: Use of hMSC of the Present Invention to Maintain Viability of Hematopoietic Stem Cells

Passage 10 MSC suspensions are seeded onto collagen type 1 plus fibronectin-coated 96-well tissue culture plates at a density of 10³ cells/well. After incubating cells in GM for 24 hours, cells are cultured in the presence of a soft gel or matrix, as described in the above Examples. The resulting mesenchymal stem cell cultures are then added to hematopoietic stem cell cultures to maintain viability of the latter cells.

In additional studies, hMSC are incubated directly on the soft gel, without prior plating in tissue culture dishes and trypsinization.

Example 15: Human Bone Marrow-Derived Mesenchymal Stem Cells (MSCS)

Summary: 250 Pa polyacrylamide gels were coated with a mixture of type 1 collagen and fibronectin. The gel coated with collagen and fibronectin had an elasticity that is similar to that of bone marrow and fat tissues. When seeded sparsely on these gels, the human MSCs halted progression through the cell cycle despite the presence of serum. However, when coupled to a stiff substrate, these non-proliferative human MSCs reentered the cell cycle.

Non-proliferative human MSCs on 250 Pa gels also were able to differentiate into adipocytes when cultured in adipogenic induction medium and into osteoblasts when transferred to a stiff substrate and incubated with osteoblast induction media. These results demonstrate that human MSCs on 250 Pa gels are quiescent but also competent to resume proliferation or initiate differentiation upon appropriate stimulus.

Materials and Methods

Materials.

Bone marrow-derived human mesenchymal stem cells were purchased from Cambrex (Walkersville, Md.). Acrylamide and bisacrylamide powders were purchased from Fisher Scientific (Pittsburgh, Pa.). Rat tail collagen type I was purchased from BD Bioscience (San Jose, Calif.). Human fibronectin was purified using procedures known in the art. (Williams E C, Janmey P A, Ferry J D, et al., “Conformational states of fibronectin. Effects of pH, ionic strength, and collagen binding,” J Biol. Chem. 1982; 257:14973-14978.) Oil Red O (ORO) was obtained from Sigma (St. Louis, Mo.). Alizarin Red S was obtained from Alfa Aesar (Ward Hill, Mass.). BrdU labeling reagent was obtained from Zymed (San Francisco, Calif.). Anti-BrdU antibody and DAPI were obtained from Invitrogen (Carlsbad, Calif.). All other chemicals used in this Example 1 were of analytical grade.

Cell Culture.

Prior to seeding on gels, bone marrow-derived human mesenchymal stem cells (MSCs) were maintained in a growth medium (GM) comprising Dulbecco's Modified Eagle Media (DMEM) with 1 g/L D-glucose (low glucose DMEM), 0.3 mg/ml L-glutamine and 100 mg/L sodium pyruvate and 10% heat inactivated fetal bovine serum on tissue culture plastic. For adipocyte differentiation, cells were exposed to two chemical induction cycles consisting of 3 days in adipogenic induction media (GM, 1 μM dexamethasone, 200 μM indomethacin, 10 μg/ml insulin and 0.5 mM 3-Isobutyl-1-methylxanthine) and 1 day in adipogenic maintenance media (GM and 10 μg/ml insulin). Undifferentiated cells were kept in GM and re-fed every 3 days. For osteoblast differentiation, cells were incubated with an osteoblast induction media (GM, 50 μM ascorbic acid-2-phosphate, 10 mM β-glycerophosphate and 100 nM dexamethasone) for 24 days, wherein the media were changed every 3-4 days. Cells were plated at a density of 5×10⁴ cells per 4.9 cm² on gels, or 1×10⁵ cells per 4.9 cm² (confluent) or 1×10⁴ cells per 4.9 cm² (sparse) on glass.

Gel Preparation and Characterization.

Polyacrylamide gels of 250 Pa and 7500 Pa were prepared using procedures known in the art with minor modification, as described in Pelham, et al. (Pelham R J, Jr., Wang Y., “Cell locomotion and focal adhesions are regulated by substrate flexibility,” Proc Natl Acad Sci USA 1997; 94:13661-13665.) Solutions of 3.0% acrylamide and 0.2% bisacrylamide (for 250 Pa gel) or 7.5% acrylamide and 0.5% bisacrylamide (7500 Pa gel), respectively, were prepared in phosphate buffered saline (PBS) (pH 7.4) to a total volume of 500 μl. Polymerization was initiated with N,N,N′,N′-tetramethylethylenediamine and ammonium persulfate. A droplet of 150 μl was deposited on a 25 mm glass coverslip previously modified with 3-aminopropyltrimethoxysilane and glutaraldehyde. 15 μl of 2% acrylic acid N-hydroxysuccinimide ester in toluene was applied to the droplet and a 25 mm chlorosilanized coverslip was placed on top of the droplet and removed after polymerization was completed, and the resulting gel was illuminated with ultraviolet light for approximately 10-15 minutes. The gels were placed into a six well polystyrene tissue culture plate and washed with phosphate buffered saline (PBS). The six well plates were pre-coated with a 1% agarose gel to prevent adhesion of cells outside of gels or coverslips. The N-succinimide acrylate on the top of the gel was reacted for one hour with a mixture of 0.1 mg/ml of rat tail collagen type 1 and 0.02 mg/ml human fibronectin. Gels were then washed 3 times with PBS and left in PBS until cells were seeded within 24 hours. Glass coverslips were submerged in rat tail collagen type 1 plus human fibronectin solution for 1 hour to coat their surface with extracellular matrix ligands.

Rheology Measurements.

To measure the dynamic shear modulus (G′) of polyacrylamide gels, 500 μl of monomer solution was polymerized between two 25 mm steel parallel plates in a hydration chamber. The shear modulus was calculated from the in-phase shear stress on a strain-controlled RFS III fluids spectrometer rheometer (Rheometrics, Piscataway, N.J.) using a 2% oscillatory shear strain at a frequency of 10 radians per second. Dynamic shear modulus (G′) was measured for relevant animal tissues. Rat tissues were dissected from the animal, kept hydrated in PBS for no longer than 1 hour prior to the measurements. Bovine tissues were purchased from a commercial slaughterhouse, transported on ice, hydrated, and warmed to 37° C. before measurements were made. Dynamic shear modulus (G′) of hydrated 8 mm diameter, 2 mm thick samples of rat tissue and hydrated 25 mm diameter, 2 mm thick samples of bovine tissue were measured at 37° C. using parallel plates with geometries matching the samples and a 2% oscillatory shear strain at a frequency of 10 radians per second. Three samples of each tissue were measured.

Quasi 3D Gel System.

Substrate sandwiches that are designed to mimic a three-dimensional environment of cells were created using methods described in Beningo, et al., modified to change the elasticity of the substrate, the composition of the ECM layer, and the weight used to bring the cells in close proximity to the coverslip, as described below. (Beningo K A, Dembo M, Wang Y L, “Responses of fibroblasts to anchorage of dorsal extracellular matrix receptors,” Proc Natl Acad Sci USA. 2004; 101:18024-18029.) Cells were seeded onto a 25 mm gel and allowed to settle for 48 hours. Excess media was removed, and a second coverslip (with and without 250 Pa polyacrylamide gel on the bottom side) was placed on top of the seeded gel. The bottom side of the second coverslip was coated with the mixture of collagen type 1 and fibronectin described above. To bring the cells into close proximity with a second coverslip, a sterilized 35 gram weight was placed on top of the sandwich for 30 seconds. After the weight was removed, the media was reintroduced, and the cells were kept in the sandwiches for 2 days. The cells were imaged immediately before applying the top coverslip and also 2 days afterward.

Imaging.

Immunostaining was performed using procedures known in the art. (Funaki M, Randhawa P, Janmey P A, “Separation of insulin signaling into distinct GLUT4 translocation and activation steps,” Mol Cell Biol. 2004; 24:7567-7577.) Fatty acid-rich vesicles were stained with ORO after 2 cycles of adipogenic induction or 8 days in growth media, as described by Shao and Lazar. (Shao D, Lazar M A, “Peroxisome proliferator activated receptor gamma, CCAAT/enhancer-binding protein alpha, and cell cycle status regulate the commitment to adipocyte differentiation,” J Biol. Chem. 1997; 272:21473-21478.) Calcium rich extracellular matrix was stained with Alizarin Red S after 24 days in osteoblast induction media in accordance with the manufacturer's instructions. BrdU incorporation was measured by incubating the cells in BrdU-containing medium overnight. Cells were fixed and stained for both BrdU and DAPI in accordance with the manufacture's instructions. In all cases, cells were imaged on a Leica DM-IRBE microscope (Wetzlar, Germany) with a Hamamatsu ORCA camera (Hamamatsu, Japan).

The projected cell area was measured using images of phalloidin staining. The images were converted to 8 bit and thresholded. Particle size was analyzed using Image J software (NIH, Bethesda, Md.). Cells were also stained with DAPI to verify that cells were not overlapping. Only isolated cells were counted.

Results

Rheological testing was conducted on bone marrow to determine the gel elasticity appropriate for studying the role of substrate compliance in maintaining a reservoir of resting human MSCs. As shown in Table 3 below, bovine bone marrow exhibited an oscillatory storage modulus (G′) of 220 Pa. The G′ of fat tissues was also measured to investigate the role of substrate stiffness in human MSC adipogenesis. Rat adipose tissues exhibited a slightly lower G′ of approximately 150 Pa. There was no statistical difference between the G′ for visceral and subcutaneous fat in rats. A polyacrylamide substrate solution of 3.0% acrylamide and 0.1% bisacrylamide was adopted to mimic the elasticity of the cells' natural environment. This polyacrylamide solution has a polymerized G′ of 250±25 Pa, which is similar to the measured G′ values of the rat and bovine tissues. In some experiments a second substrate with a storage modulus of 7500±250 Pa (similar to that of muscle tissue) served as a control. (Engler A J, Griffin M A, Sen S, et al., “Myotubes differentiate optimally on substrates with tissue-like stiffness: pathological implications for soft or stiff microenvironments,” J. Cell Biol. 2004; 166:877-887.)

TABLE 3 Species Bovine Rat Rat Tissue Bone Marrow Visceral Fat Subcutaneous Fat Elasticity 220 ± 50 Pa 130 ± 70 Pa 160 ± 70 Pa (mean ± SD)

FIGS. 9A-9I show images of human MSC at an initial plating density of 2000 cells/cm² on 250 Pa (FIGS. 9A, 9D and 9H), 7500 Pa (FIGS. 9B, 9E, and 9I), and glass (FIGS. 9C, 9F and 9J) substrates. As shown in FIGS. 9A-9C, cells were plated on collagen type I and fibronectin-coated substrates and imaged in phase contrast mode after 24 hours of incubation in growth media (GM). Arrows indicate the location of the cells. FIGS. 9D-1F show images at the same locations after 7 days of incubation in GM. Cells were kept at 37° C. during imaging. Representative images from 2 independent experiments are shown. As shown in FIGS. 9H-9J, F-actin in human MSC was labeled with fluorescein isothiocianate (FITC) conjugated phalloidin two days after seeding. Also reported is the mean projected area±standard deviation. At least 40 cells in seven randomly chosen fields were counted for each condition. The scale bars in FIGS. 9A-9F are 900 μm, and the scale bars in FIGS. 9G-9I are 20 μm.

After two days on 250 Pa gels coated with a mixture of fibronectin and collagen I, human MSCs had relatively small, rounded morphologies with a disorganized F-actin cytoskeleton, as shown in FIGS. 9A and 9G. The human MSCs had an average projected cell area of only 650±250 μm², which is significantly lower than a spread area of 3500±1100 μm² as measured on glass coated with the same adhesion proteins. A similar phenotype has been observed in fibroblasts, endothelial cells, and astrocytes on 250 Pa gels. (Yeung T, Georges P C, Flanagan L A, et al., “Effects of substrate stiffness on cell morphology, cytoskeletal structure, and adhesion,” Cell Motil Cytoskeleton. 2005; 60:24-34; Pelham R J, Jr., Wang Y, “Cell locomotion and focal adhesions are regulated by substrate flexibility,” Proc Natl Acad Sci USA. 1997; 94:13661-13665; Georges P C, Miller W J, Meaney D F, et al., “Matrices with compliance comparable to that of brain tissue select neuronal over glial growth in mixed cortical cultures,” Biophysical Journal. 2006; 90:3012-3018.) When the culture time was extended to seven days, some of the cells strengthened their adhesion to the compliant matrix and began to spread. However, as shown in FIG. 1D, the number of cells did not increase appreciably. Accordingly, soft gels induced a round shape, disorganized F-actin and cell cycle arrest in bone marrow-derived human MSCs.

In comparison, human MSCs maintained on 7500 Pa gels for two days were partially spread with a projected cell area of 2600±1500 μm². As shown in FIGS. 9B and 9E, the human MSCs exhibited some actin organization but few stress fibers. After seven days, the human MSCs apparently increased their numbers. As shown in FIG. 9H, they also became increasingly spread upon cell-cell contact. As shown in FIGS. 9C, 9F, and 9I, human MSCs on glass exhibited a spread morphology, had abundant stress fibers, and proliferated rapidly.

To investigate whether matrix elasticity may change the proliferative behavior of human MSC, a 5-bromo-2′-deoxyuridine 5′-triphosphate (BrdU) incorporation assay was performed on cells cultured on various substrates, as shown in FIG. 10. FIG. 10 shows the percentage of cells that tested positive for BrdU uptake, indicating cells proliferated during the incubation period with BrdU, on substrates of varying compliance. Cells were plated on substrates for 48 hours before incubating the cells in media containing BrdU overnight. Cells were kept in serum-containing media for the entire period, except for the Glass Confluent, which was serum starved for 24 hours before the BrdU was added in serum free media. Nuclei of cells were stained with anti-BrdU and the nuclei were counterstained with 4′,6-diamidino-2-phenylindole (DAPI). At least 50 DAPI-positive cells were checked for BrdU-staining on each substrate, and data is expressed as mean±SE (standard error) of three independent experiments, with *p<0.01, confirming statistical significance.

After an overnight incubation with BrdU, virtually no human MSC adhering to 250 Pa gels incorporated BrdU. Thus, DNA replication was suppressed despite the presence of serum. (DNA replication is a necessary step in human MSC cell division.) On 7500 Pa gels, approximately half of the cells replicated their DNA in 24 hours. When sparsely seeded on glass, over 80% of the cells exhibited nuclear BrdU staining. These results imply that substrate compliance can significantly affect progression of the cell cycle in human MSCs.

Damaged viability of human MSCs on a soft substrate could explain the observations that cells on 250 Pa gels round up and cease proliferating despite the presence of serum. However, human MSCs on 250 Pa gels did not incorporate trypan blue, which indicates that these cells were not dead. To determine whether the soft gel-induced cell cycle arrest is reversible, the cells were put in a quasi 3D environment, as shown in FIGS. 11A-11D. FIGS. 11A-11D illustrate the effect of a quasi 3D environment on stem cell shape and proliferation. Cells were seeded onto 250 Pa gels and imaged after two days in serum containing media (FIGS. 11A and 11B). On day 2 a top substrate of either another 250 Pa gel (FIG. 11C) or a glass coverslip (FIG. 11D) was used to sandwich the cells in a quasi 3D environment. Two days later the cells were imaged again at the same locations. In FIGS. 11A-11D, the scale bar is 100 μm.

A 250 Pa gel or a glass coverslip, each coated with the same matrix ligand as the bottom gels, were placed on top of round non-proliferating human MSCs on 250 Pa gels. Cells sandwiched between the two 250 Pa gels either remained round or spread to a small degree. As shown in FIG. 11C, no apparent increase in the number of these cells was observed. On the other hand, as shown in FIG. 11D, cells facing glass coverslips on top proliferated and became spindle-shaped. Once human MSCs firmly adhered to the upper glass surface, they detached from the soft substrate. Accordingly, the human MSCs on 250 Pa gels were competent to resume proliferation upon receiving a mechanical signal from a stiffer substrate.

The temporary growth arrest of human MSCs on 250 Pa gels raises the question of whether these cells are competent to differentiate. Differentiation is achieved through a highly coordinated set of events, including growth arrest and expression of cell lineage-restricted phenotypes. Substrate elasticity has been reported to specify the lineage into which human MSCs differentiate. (Engler A J, Sen S, Sweeney H L, Discher D E, “Matrix elasticity directs stem cell lineage specification,” Cell. 2006 Aug. 25; 126(4):677-89.) Adipocyte differentiation of human MSCs was tested on gels having an elasticity of 250 Pa, which is comparable to the elasticity of fat tissues.

When cells on matrices with various stiffnesses were treated with an adipogenic differentiation medium, there was an inverse relationship between the percentage of cells that incorporated BrdU into their nuclei and the percentage of cells that accumulated lipid droplets detected by ORO staining.

FIGS. 12A and 12B show the response of human MSCs to adipogenic induction media. FIG. 12A shows Oil Red O (ORO) staining for lipid accumulation in human MSCs. Cells were seeded on to 250 Pa, 7500 Pa or glass substrates and subjected to either 8 days of growth media (−), or two cycles of adipogenic induction (+). FIG. 12B shows the dose response of human MSC to chemical differentiation factors on either 250 Pa gels (●) or glass (▬). Cells were seeded at densities of 2,000 cells/cm² on gels and 20,000 cells/cm² on glass. At least 50 cells were counted on each substrate. The data in FIGS. 12A and 12B are expressed as mean±SE of three independent experiments and are statistically significant (*p<0.02). Experiments A and B were carried out with different batches of human MSCs.

As shown in FIG. 12A, approximately 75% of cells sparsely seeded on 250 Pa gels accumulated lipid droplets, whereas only approximately 20% of cells sparsely seeded on 7500 Pa gels and 2% of cells sparsely seeded on glass coverslips responded to adipogenic differentiation medium by accumulating lipid droplets. Notably, human MSCs on 250 Pa gels did not accumulate lipid droplets without incubation in an adipogenic differentiation medium. These results indicate that a soft matrix facilitates adipogenic differentiation of human MSCs.

Adipogenic differentiation of human MSCs is typically achieved by inducing a confluent monolayer culture on glass. However, after 8 days in induction media, a higher percentage differentiation was observed in sparse cells induced on soft gels than in confluent cells on glass. To further determine how mechanical signals from a soft gel enhance chemically induced adipogenesis, the sensitivity of human MSCs on 250 Pa gels to an adipogenic differentiation medium was tested by inducing growth arrest in two environments: (1) sparsely seeded on 250 Pa gels and (2) densely seeded on glass coverslips. The adipogenic differentiation rate was compared between these two conditions in response to decreasing concentrations of chemical induction factors. As shown in FIG. 12B, as the concentration of the adipogenic factors decreased, human MSCs on 250 Pa gels exhibited a response similar to that of human MSCs on glass coverslips. Although culturing on 250 Pa gels rendered sparsely seeded human MSCs competent to adipogenic differentiation, this environment did not affect the sensitivity of human MSCs to their adipogenic differentiation medium.

Efficient adipogenic differentiation of growth-arrested human MSCs on 250 Pa gels raises the possibility that these non-proliferative cells may have differentiated into preadipocytes and committed to an adipogenic lineage, instead of remaining quiescent stem cells. To determine whether these cells are quiescent stem cells or differentiated preadipocytes, human MSCs were sparsely seeded on a soft gel for two days, transferred to a glass coverslip using the quasi 3D method discussed above, and finally cultured in osteoblast induction media for 24 days. (As discussed above, cells on 250 Pa gels that transferred to a stiff substrate upon contact resumed proliferation and acquired a spindle phenotype typical of human MSCs on tissue culture plastic.)

FIGS. 13A and 13B illustrate calcium deposition visualized with Alizarin Red S after stimulation with osteoinduction media. As shown in FIG. 13A, cells were cultured on a soft gel for two days then transferred to a glass coverslip using the quasi 3D method and then incubated with osteoinduction media for 24 days. As shown in FIG. 13B, human MSCs were culture on a glass coverslip for 24 days in osteoinduction media. In FIGS. 13A and 13B, the scale bar is 200 μm.

After 24 days in osteoblast induction media, calcium-rich extracellular matrix was clearly visible in the culture dish and stained positive with Alizarin Red S, as shown in FIG. 13A. Matrix mineralization is a late stage marker of osteoblast differentiation. (Kundu A K, Putnam A J, “Vitronectin and collagen I differentially regulate osteogenesis in mesenchymal stem cells,” Biochem Biophys Res Commun. 2006; 347:347-357.)

For comparison, cells never cultured on a soft gel were seeded on a glass coverslip and treated with osteoblast induction media for the same length of time. As expected, these substrates also stained positive for calcium deposition, as shown in FIG. 13B. Without stimulation by osteoblast induction media, neither of the conditions produced extracellular matrix that stained with Alizarin Red S. These results demonstrate that human MSCs on 250 Pa gels maintain their multilineage potential. Accordingly, these results verify that the human MSCs seeded on soft gels do not differentiate but rather remain quiescent as stem cells. 

What is claimed is:
 1. A mesenchymal stem cell (MSC) isolated from its biological source, adhered ex vivo onto the surface of a gel or a gel matrix and in the presence of nutrient material, wherein the surface of said gel or said gel matrix has a rigidity of 250 Pa in the microenvironment of the MSC and comprises adhesion molecules, and in a quiescent state such that the MSC is arrested in the cell cycle; wherein said quiescent state is characterized by (i) a lack of proliferation, (ii) a lack of differentiation, (iii) the ability of the MSC to express proteins, and (iv) the ability of the MSC to resume proliferation and differentiation upon exposure to a chemical stimulus, a mechanical stimulus, a physical factor or a combination thereof; and wherein said MSC exhibits a rounded morphology.
 2. The mesenchymal stem cell of claim 1, wherein the MSC is arrested in the G1 phase or the G2 phase.
 3. The mesenchymal stem cell of claim 1, wherein said mesenchymal stem cell is a bone marrow-derived mesenchymal stem cell (MSC), a renal stem cell, a skeletal muscle-derived MSC, bone-derived MSC, a dental pulp MSC, a cardiac muscle-derived MSC, a synovial-fluid derived MSC, an umbilical cord MSC or an adipose-derived MSC.
 4. The mesenchymal stem cell of claim 1, wherein said cell does not incorporate BrdU.
 5. The mesenchymal stem cell of claim 1, wherein said cell does not incorporate Trypan Blue staining.
 6. The mesenchymal stem cell of claim 1, wherein the adhesion molecules comprise collagen and fibronectin.
 7. The mesenchymal stem cell of claim 1, wherein the physical factor is pressure, temperature, or a combination of pressure and temperature.
 8. A mesenchymal stem cell (MSC) isolated from its natural in vivo microenvironment, adhered onto the surface of a gel or a gel matrix and in the presence of nutrient material, wherein the surface of said gel or said gel matrix has a rigidity of 250 Pa in the microenvironment of the MSC and comprises adhesion molecules, and in a quiescent state such that the MSC is arrested in the cell cycle; wherein said quiescent state is characterized by (i) a lack of proliferation, (ii) a lack of differentiation, (iii) the ability of the MSC to express proteins, and (iv) the ability of the MSC to resume proliferation and differentiation upon exposure to a chemical stimulus, a mechanical stimulus, a physical factor, or a combination thereof; and wherein said cell exhibits a rounded morphology.
 9. The mesenchymal stem cell of claim 8, wherein the MSC is arrested in the G1 phase or the G2 phase.
 10. The mesenchymal stem cell of claim 8, wherein said mesenchymal stem cell is a bone marrow-derived mesenchymal stem cell (MSC), a renal stem cell, a skeletal muscle-derived MSC, bone-derived MSC, a dental pulp MSC, a cardiac muscle-derived MSC, a synovial-fluid derived MSC, an umbilical cord MSC or an adipose-derived MSC.
 11. The mesenchymal stem cell of claim 8, wherein said cell does not incorporate BrdU.
 12. The mesenchymal stem cell of claim 8, wherein said cell does not incorporate Trypan Blue staining.
 13. The mesenchymal stem cell of claim 8, wherein the adhesion molecules comprise collagen and fibronectin.
 14. The mesenchymal stem cell of claim 8, wherein the physical factor is pressure, temperature, or a combination of pressure and temperature.
 15. The mesenchymal stem cell of claim 1, wherein said gel or gel matrix comprises acrylamide and bisacrylamide.
 16. The mesenchymal stem cell of claim 8, wherein said gel or gel matrix comprises acrylamide and bisacrylamide.
 17. The mesenchymal stem cell of claim 1, wherein the adhesion molecules comprise collagen.
 18. The mesenchymal stem cell of claim 8, wherein the adhesion molecules comprise collagen.
 19. The mesenchymal stem cell of claim 1, wherein the adhesion molecules comprise fibronectin.
 20. The mesenchymal stem cell of claim 8, wherein the adhesion molecules comprise fibronectin. 